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Record 1 of 74
Author(s):	Delone NB; Krainov VP
Title:	AC-Stark shift of atomic levels
Source:	USPEKHI FIZICHESKIKH NAUK 1999, Vol 169, Iss 7, pp 753-772
No. cited references:	79
Addresses:	Delone NB, Russian Acad Sci, Inst Gen Phys, 38 Vavilov St, Moscow 117942, Russia. Russian Acad Sci, Inst Gen Phys, Moscow 117942, Russia. Moscow Inst Phys & Technol, Dolgoprudnyi 141700, Moscow Region, Russia.
KeywordsPlus:	FREQUENCY LASER FIELDS; MULTIPHOTON IONIZATION; DYNAMIC POLARIZABILITY; PHOTODETACHMENT THRESHOLD; ELECTROMAGNETIC-FIELD; TUNNELING IONIZATION; PERTURBATION-SERIES; HIGH-INTENSITY; RADIATION; HYDROGEN
Abstract:	Calculated and experimental data on the AC-Stark shift of atomic levels in an external, subatomic-strength alternating field are considered. Theoretical predictions concerning the perturbation of atomic spectra by fields of atomic and superatomic strength are discussed. The limiting value of the atomic Stark shift in a light-frequency radiation field is estimated.
Cited references:	AGOSTINI P-1989-J-PHYS-B-ATOM-MOL-PH-V22-P1472 AGOSTINI P-1989-PHYS-REV-LETT-V63-P2208 ALLILUEV SP-1974-ZH-EKSP-TEOR-FIZ+-V66-P1283 AMMOSOV MV-1997-LASER-PHYS-V7-P79 ANDREYEV SP-1984-ZH-EKSP-TEOR-FIZ+-V86-P866 BAKOS JS-1977-PHYS-REP-V31-P209 BAYFIELD J-1979-PHYS-REP-V51-P318 BAYFIELD JE-1981-PHYS-REV-A-V24-P138 BEIGMAN IL-1994-J-PHYS-B-AT-MOL-OPT-V27-P5833 BEKENSTEIN JD-1969-PHYS-REV-V188-P130 BENASSI L-1980-J-PHYS-B-AT-MOL-OPT-V13-P911 BENASSI L-1979-PHYS-REV-LETT-V42-P704 BERSON IJ-1975-J-PHYS-B-AT-MOL-OPT-V8-P3078 BETE GA-1969-KVANTOVAYA-MEKHANIKA BONCHBRUEVICH AM-1967-USP-FIZ-NAUK-V93-P71 BONCHBRUEVICH AM-1969-ZH-EKSP-TEO-V56-P144 BONIN KD-1993-PHYS-REV-A-V47-P944 BRESONS IY-1983-ZH-EKSP-TEOR-FIZ-V85-P70 BUREEVA LA-1997-VOZMUSHCHENNYI-ATOM CRANCE M-1990-J-OPT-SOC-AM-B-V7-P449 DAVIDSON MD-1993-PHYS-REV-LETT-V71-P2192 DAVYDKIN VA-1971-ZHETF-V60-P125 DEBOER MP-1994-J-PHYS-B-AT-MOL-OPT-V27-P721 DEBOER MP-1993-PHYS-REV-LETT-V71-P3263 DELONE NB-1984-ATOM-SILNOM-SVETOVOM DELONE NB-1992-LASER-PHYSICS-V2-P654 DELONE NB-1994-SPRINGER-SERIES-ATOM-V13 DELONE NB-1985-SPRINGER-SERIES-CHEM-V28 DELONE NB-1998-USP-FIZ-NAUK+-V168-P531 DELONE NB-1995-USP-FIZ-NAUK+-V165-P1295 DELONE NB-1983-USP-FIZ-NAUK+-V140-P355 DELONE NB-1976-USP-FIZ-NAUK+-V120-P3 DELONE NB-1982-ZH-EKSP-TEOR-FIZ+-V83-P2021 DORR M-1990-PHYS-REV-LETT-V64-P2003 ELYASHEVICH MA-1962-ATOMNAYA-MOL-SPEKTRO FEARNSIDE AS-1995-PHYS-REV-A-V51-P1471 FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 FRISH SE-1963-OPTICHESKIE-SPEKTRY GAVRILA M-1984-PHYS-REV-LETT-V52-P613 HUILLIER L-1989-J-OPT-SOC-AM-B-V6-P1644 JONES RR-1991-PHYS-REV-LETT-V67-P3215 KAMKE E-1976-SPRAVOCHNIK-OBYKNOVE KELDYSH LV-1964-ZH-EKSP-TEOR-FIZ-V47-P1945 KOCH PM-1977-INT-C-MULT-PROC-POST KRAINOV VP-1993-LASER-PHYS-V3-P756 KRAINOV VP-1993-ZH-EKSP-TEOR-FIZ-V103-P1143 KRILOVETSKY AA-1997-LASER-PHYS-V7-P542 KULYAGIN RV-1993-LASER-PHYSICS-V3-P644 LETOKHOV VS-1987-LAZERNAYA-FOTOIONIZA MANAKOV NL-1986-PHYS-REP-V141-P320 MANAKOV NL-1989-ZH-EKSP-TEOR-FIZ+-V95-P790 MANAKOV NL-1975-ZH-EKSP-TEOR-FIZ+-V69-P842 MAQUET A-1983-PHYS-REV-A-V27-P2946 MARINESCU M-1994-PHYS-REV-A-V49-P5103 MEVEL E-1992-J-PHYS-B-AT-MOL-OPT-V25-PL401 MEVEL E-1993-PHYS-REV-LETT-V70-P406 MUR VD-1993-LASER-PHYS-V3-P462 MUR VD-1993-PISMA-ESKP-TEOR-FIZ-V57-P406 NG K-1987-PHYS-REV-A-V35-P2508 NIKISHOV AI-1964-ZH-EKSP-TEOR-FIZ-V46-P776 OBRIAN TR-1994-PHYS-REV-A-V49-PR649 PONT M-1987-PHYS-LETT-A-V123-P469 PONT M-1989-PHYS-REV-A-V40-P5659 PONT M-1988-Z-PHYS-D-ATOM-MOL-CL-V9-P297 POPOV VS-1990-PHYS-LETT-A-V149-P418 RADTSIG AA-1986-PARAMETRY-ATOMOV-ATO RAPOPORT LP-1997-OPT-SPEKTROSK-V83-P888 RAPOPORT LP-1978-TEORIYA-MNOGOFOTONNY RAPOPORT LP-1994-ZH-EKSP-TEOR-FIZ+-V105-P534 RITUS VI-1966-ZH-EKSP-TEO-V51-P1544 ROTTKE H-1989-Z-PHYS-D-V15-P133 SILVERMAN JN-1988-CHEM-PHYS-LETT-V153-P61 SMIRNOV BM-1982-VOZBUZHDENNYE-ATOMY SZOKE A-1989-PHYS-REV-A-V40-P2766 TRAINHAM R-1987-PHYS-REV-LETT-V59-P2291 VOLKOVA EA-IN-PRESS-ZHETF VOLKOVA EA-1997-ZH-EKSP-TEOR-FIZ-V111-P1194 VOLKOVA EA-1996-ZH-EKSP-TEOR-FIZ+-V109-P1586 ZELDOVICYB-1973-USP-FIZ-NAUK+-V110-P139
Source item page count:	20
Publication Date:	JUL
IDS No.:	223XH
29-char source abbrev:	USP FIZ NAUK

Record 2 of 74
Author(s):	Popov VS; Karnakov BM; Mur VD
Title:	Lorentz ionization of atoms in a strong magnetic field
Source:	JOURNAL OF EXPERIMENTAL AND THEORETICAL PHYSICS 1999, Vol 88, Iss 5, pp 902-912
No. cited references:	42
Addresses:	Popov VS, Inst Theoret & Expt Phys, Moscow 117218, Russia. Inst Theoret & Expt Phys, Moscow 117218, Russia. Moscow Engn Phys Inst, Moscow 115409, Russia.
KeywordsPlus:	PERTURBATION-THEORY; STARK RESONANCES; HYDROGEN-ATOM; HIGH ORDERS; 1/N-EXPANSION
Abstract:	Lorentz ionization emerges due to the motion of atoms or ions in a strong magnetic field. We use the semiclassical approximation to calculate the probability w(L) of Lorentz ionization. We also find the stabilization factor S, which takes into account the reduction by the magnetic field of the probability of ionization decay of the bound s state. We estimate the probabilities w(L) in magnetic-cumulation experiments and in astrophysics. We also qualitatively examine the dynamics of the magnetic cumulation process with allowance for the conductivity of the shell. Finally, we discuss a paradox related to the use of the quasistationary solution at the shell expansion stage.(C) 1999 American Institute of Physics. [S1063-7761(99)00905-1].
Cited references:	ALLILUEV SP-1980-PHYS-LETT-A-V78-P43 ALLILUEV SP-1979-PHYS-LETT-A-V73-P103 ASKARYAN GA-1996-HE-LIVED-US-MEMORIES-P125 BENASSI L-1979-PHYS-REV-LETT-V42-P704 BENASSI L-1979-PHYS-REV-LETT-V42-P1430 BITTER F-1965-SCI-AM-JUL-P64 BREZIN E-1970-PHYSICAL-REVIEW-D-V2-P1191 CARSLAW HS-1945-INTRO-MATH-THEORY-CO DAMBURG RJ-1978-J-PHYS-B-AT-MOL-OPT-V11-P1921 DAVYDOV AS-1976-SOLID-STATE-THEORY DELONE NB-1998-PHYS-USP-V41-P469 ELETSKIELETSKII AV-1980-SOV-PHYS-DOKL-V25-P27 FABRIKA SN-1998-129-RUSS-AC-SCI-SPEC FERNANDEZ FM-1996-PHYS-REV-A-V54-P1206 FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 GRADSHTEYN IS-1980-TABLES-INTEGRALS-SUM HEHENBERM-1974-PHYS-REV-A-V10-P1494 HERBST IW-1978-PHYS-REV-LETT-V41-P67 HERBST IW-1978-PHYS-REV-LETT-V41-P1759 JOHNSON BR-1963-PHYS-REV-LETT-V51-P2280 KARNAKOV BM-1997-JETP-LETT+-V65-P405 LANDAU LD-1984-ELECTRODYNAMICS-CONT LANDAU LD-1977-QUANTUM-MECH-NONRELA LIDE DR-1994-HDB-CHEM-PHYSICS MUR VD-1993-LASER-PHYS-V3-P462 MUR VD-1999-SOV-PHYS-JETP-V88-P286 PAVLOVSKII AI-1995-COLLECTED-PAPERS-AD-P85 POPOV VS-1996-JETP-LETT+-V63-P417 POPOV VS-1997-PHYS-LETT-A-V229-P306 POPOV VS-1993-PHYS-LETT-A-V173-P63 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1987-PHYS-LETT-A-V124-P77 POPOV VS-1998-SOV-PHYS-JETP-V86-P860 SAKHAROV AD-1965-COLLECTED-PAPERS-AD SAKHAROV AD-1966-SOV-PHYS-DOKL-V10-P1045 SAKHAROV AD-1966-SOV-PHYS-USP-V9-P294 SCHWINGER J-1951-PHYS-REV-V82-P664 SEIPP I-1997-ASTRON-ASTROPHYS-V318-P990 SEIPP I-1996-J-PHYS-B-AT-MOL-OPT-V29-P1 SILVERSTONE HJ-1979-PHYS-REV-LETT-V43-P1498 VAINBERG VM-1998-16-C-FUND-AT-SPECTR-P130 WICKRAMASINGHE DT-1988-ASTROPHYS-J-V327-P222
Source item page count:	11
Publication Date:	MAY
IDS No.:	206BX
29-char source abbrev:	J EXP THEOR PHYS

Record 3 of 74
Author(s):	Watson DK; McKinney BA
Title:	Improved large-N limit for Bose-Einstein condensates from perturbation theory
Source:	PHYSICAL REVIEW A 1999, Vol 59, Iss 5, pp 4091-4094
No. cited references:	18
Addresses:	Watson DK, Univ Oklahoma, Dept Phys & Astron, Norman, OK 73019 USA. Univ Oklahoma, Dept Phys & Astron, Norman, OK 73019 USA.
KeywordsPlus:	EXPANSION
Abstract:	We present a perturbation solution of a model Bose-Einstein Hamiltonian derived by Bohn, Esry, and Greene. In our solution we use 1/N as the perturbation parameter, where N is the number of particles in the condensate. Ground-state energies are reported for parameters approximating the Joint Institute for Laboratory Astrophysics Rb-87 experiments. We predict the critical number of atoms with negative scattering lengths that can be trapped using the effective trap frequency of the first-order equation. The N-->infinity perturbation limit, which retains a single term beyond the conventional Thomas-Fermi limit, gives ground-state energies that agree to three digits with converged results, thus providing a much improved limit for large N. [S1050-2947(99)00305-4].
Cited references:	ANDERSON MH-1995-SCIENCE-V269-P198 AVERY J-1989-HYPERSPHERICAL-HARMO BERLIN TH-1952-PHYS-REV-V86-P821 BOHN JL-COMMUNICATION BOHN JL-1998-PHYS-REV-A-V58-P584 BRADLEY CC-1997-PHYS-REV-LETT-V78-P985 DUNN M-1994-J-CHEM-PHYS-V101-P5987 FETTER AL-1997-J-LOW-TEMP-PHYS-V106-P643 HERSCHBACH DR-1992-DIMENSIONAL-SCALING MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 PEREZGARCIA VM-1997-PHYS-REV-A-V56-P1424 POPOV VS-1990-PHYS-LETT-A-V149-P425 RUDNICK J-1987-SCIENCE-V237-P384 SMIRNOV YF-1977-SOV-J-PART-NUCL-V8-P344 STANLEY HE-1968-PHYS-REV-V176-P718 STOOF HTC-1997-J-STAT-PHYS-V87-P1353 TSIPIS CA-1996-NATO-C-BOOK-V8 UEDA M-1998-PHYS-REV-LETT-V80-P1576
Source item page count:	4
Publication Date:	MAY
IDS No.:	197UB
29-char source abbrev:	PHYS REV A

Record 4 of 74
Author(s):	Killingbeck JP
Title:	Subsequence summation and the m function
Source:	PHYSICS LETTERS A 1999, Vol 253, Iss 1-2, pp 28-32
No. cited references:	10
Addresses:	Killingbeck JP, Observ Besancon, 41 Ave Observ, BP 1615, F-25010 Besancon, France. Observ Besancon, F-25010 Besancon, France. Univ Hull, Dept Math, Hull HU6 7RX, N Humberside, England.
KeywordsPlus:	TRANSFORMATIONS
Abstract:	A complex variable modification of the Hill determinant method is shown to give accurate values for the Weyl-Titchmarsh mo(lambda) function used in the spectral theory of the Schrodinger equation. A method of geometric sampling of partial sums is tested and shown to produce well converged results from some extremely slowly converging spectral sums for the mo(lambda) function associated with the potential V(x) = x(2). (C) 1999 Elsevier Science B.V.
Cited references:	BREZINSKI C-1977-ACCELERATION-CONVERG KILLINGBECK J-1988-PHYS-LETT-A-V132-P223 KILLINGBECK JP-1995-PHYS-LETT-A-V206-P279 LEVIN D-1973-INT-J-COMPUT-MATH-V3-P371 SERGEEV AV-1998-J-PHYS-A-MATH-GEN-V31-P4301 SHANKS D-1995-J-MATHS-PHYS-V34-P1 VANDENBROECK JM-1979-SIAM-J-MATH-ANAL-V10-P658 WEYL H-1910-MATH-ANN-V68-P220 WIMP J-1981-SEQUENCE-TRANSFORMAT WYNN P-1956-MTAC-V10-P91
Source item page count:	5
Publication Date:	MAR 15
IDS No.:	176ZP
29-char source abbrev:	PHYS LETT A

Record 5 of 74
Author(s):	Dunn M; Watson DK
Title:	Large-dimension limit of higher-angular-momentum states of two-electron atoms
Source:	PHYSICAL REVIEW A 1999, Vol 59, Iss 2, pp 1109-1124
No. cited references:	235
Addresses:	Dunn M, Univ Oklahoma, Dept Phys & Astron, Norman, OK 73019 USA. Univ Oklahoma, Dept Phys & Astron, Norman, OK 73019 USA.
KeywordsPlus:	SHIFTED 1/N EXPANSION; LARGE-N-EXPANSION; DOUBLY-EXCITED-STATES; MOLECULAR-ORBITAL DESCRIPTION; INVERSE SCATTERING TRANSFORMATION; HELIUM ISOELECTRONIC SEQUENCE; SCREENED COULOMB POTENTIALS; BARRIER STARK RESONANCES; QUASI-STATIONARY STATES; WEAKLY-BOUND SYSTEMS
Abstract:	To apply the methods of dimensional scaling to higher-angular-momentum states, a formalism needs to be developed which factors the D-dimensional rotational degrees of freedom from the internal degrees of freedom. The rotational degrees of freedom multiply with increasing dimensionality, while the internal degrees of freedom remain finite in number. A suitable expansion which achieves this has been presented by the authors recently and is an N-electron D-dimensional generalization of the Schwartz expansion. A derivation of the coupled differential equations in the internal variables that result from the application of the Hamiltonian to this wave-function expansion for the atomic two-electron system has been presented by the authors in another recent paper. The coupled differential equations admit continuation in D and clearly show the complete spectrum of exact interdimensional degeneracies of the two-electron system. However, to apply the methods of dimensional scaling to the two-electron system, the system of coupled differential equations have to be solved for large D. This paper concerns itself with this issue. [S1050-2947(97)07608-7].
Cited references:	ADER JP-1983-PHYS-LETT-A-V97-P178 ALVES NA-1988-J-PHYS-A-MATH-GEN-V21-P3215 ANDREW K-1990-AM-J-PHYS-V58-P1177 ATAG S-1988-PHYS-REV-A-V37-P2280 AU CK-1991-J-PHYS-B-AT-MOL-OPT-V24-P4671 AVAN J-1984-NUCL-PHYS-B-V237-P159 AVAN J-1983-NUCL-PHYS-B-V224-P61 AVAN J-1984-PHYS-REV-D-V29-P2891 AVAN J-1984-PHYS-REV-D-V29-P2904 AVERY J-1993-DIMENSIONAL-SCALING-P139 AVERY J-1989-HYPERSPHERICAL-HARMO AVERY J-1992-INT-J-QUANTUM-CHEM-V41-P673 AVERY J-1991-INT-J-QUANTUM-CHEM-V39-P657 AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BAG M-1992-PHYS-REV-A-V46-P6059 BELOV AA-1989-PHYS-LETT-A-V142-P389 BELOV AA-1989-THEOR-MATH-PHYS+-V81-P1294 BELOV AA-1990-ZH-EKSP-TEOR-FIZ+-V98-P25 BENDER CM-1982-PHYS-REV-A-V25-P1305 BENDER CM-1992-PHYS-REV-LETT-V68-P3674 BERA PK-1993-PHYS-REV-A-V48-P4764 BERLIN TH-1952-PHYS-REV-V86-P821 BERRY RS-1988-ADV-CHEM-PHYS-V70-P35 BERRY RS-1989-CONTEMP-PHYS-V30-P1 BERRY RS-1993-DIMENSIONAL-SCALING-P485 BLEIL R-1995-INT-J-QUANTUM-CHEM-S-V29-P349 BLEIL R-1995-J-CHEM-PHYS-V103-P6529 BLINDER SM-1984-J-MATH-PHYS-V25-P905 BOERNER H-1983-REPRESENTATIONS-GROU BOLLE D-1984-PHYS-REV-A-V30-P1279 BOTTCHER C-1994-PHYS-REV-A-V49-P1714 BOYA LJ-1994-PHYS-REV-A-V50-P4397 BUTLER GJ-1983-J-MATH-BIOL-V17-P131 CARZOLI J-IN-PRESS-PHYS-REV-A CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P735 CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P2403 CHATTERJEE A-1990-PHYS-REP-V186-P249 CHATTERJEE A-1986-PHYS-REV-A-V34-P2470 CHISHOLM CDH-1976-GROUP-THEORETICAL-TE-PCH8 CHRISTIANSEN H-1989-PHYS-REV-A-V40-P1760 DAHL JP-1993-DIMENSIONAL-SCALING-P165 DEVEGA HJ-1979-COMMUN-MATH-PHYS-V70-P29 DIRAC PAM-1958-PRINCIPLES-QUANTUM-M DOLGOV AD-1979-PHYS-LETT-B-V86-P185 DOREN DJ-1985-CHEM-PHYS-LETT-V118-P115 DOREN DJ-1987-J-CHEM-PHYS-V87-P433 DOREN DJ-1986-J-CHEM-PHYS-V85-P4557 DOREN DJ-1988-J-PHYS-CHEM-US-V92-P1816 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DOREN DJ-1986-PHYS-REV-A-V34-P2665 DUNN M-1996-ANN-PHYS-NEW-YORK-V251-P266 DUNN M-1996-ANN-PHYS-NEW-YORK-V251-P319 DUNN M-1994-J-CHEM-PHYS-V101-P5987 DUNN M-1990-J-PHYS-B-AT-MOL-OPT-V23-P2435 DUNN M-1993-J-PHYS-CHEM-US-V97-P2457 DUNN M-UNPUB DUTT R-1987-J-PHYS-B-AT-MOL-OPT-V20-P2437 DUTT R-1986-J-PHYS-B-AT-MOL-OPT-V19-P3411 DUTT R-1985-J-PHYS-B-AT-MOL-OPT-V18-P3311 DUTT R-1986-PHYS-REV-A-V34-P777 DUTT R-1986-Z-PHYS-D-ATOM-MOL-CL-V2-P207 EDMONDS AR-1960-ANGULAR-MOMENTUM-QUA ERKOC S-1986-PHYS-REV-D-V33-P588 FANO U-1993-NEW-METHODS-QUANTUM-P225 FEAGIN JM-1988-PHYS-REV-A-V37-P4599 FEAGIN JM-1986-PHYS-REV-LETT-V57-P984 FERRELL RA-1974-PHYS-REV-A-V9-P846 FRANTZ DD-1988-CHEM-PHYS-V126-P59 FRANTZ DD-1989-PHYS-REV-A-V40-P1175 GALLUP GA-1959-J-MOL-SPECTROSC-V3-P673 GANGOPADHYAY RS-1984-PHYS-REV-A-V30-P594 GANGYOPADHYAY RS-1985-PHYS-REV-D-V32-P3312 GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GERMANN TC-1995-PHYS-REV-LETT-V74-P658 GONZALEZ A-1992-FEW-BODY-SYST-V13-P105 GONZALEZ A-1991-FEW-BODY-SYST-V10-P43 GONZALEZ A-1993-J-PHYS-B-AT-MOL-OPT-V26-P1253 GOODSON DZ-1993-DIMENSIONAL-SCALING-P275 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 GOODSON DZ-1992-PHYS-REV-A-V46-P5428 GOODSON DZ-1991-PHYS-REV-A-V44-P97 GOODSON DZ-1991-PHYS-REV-A-V43-P4617 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 GOSCINSKI O-1986-INT-J-QUANTUM-CHEM-V29-P897 HAGG L-1993-DIMENSIONAL-SCALING-P315 HAMERMESH M-1989-GROUP-THEORY-ITS-APP-PCH10 HERRICK DR-1983-ADV-CHEM-PHYS-V52-P1 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-J-MATH-PHYS-V16-P1047 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1993-DIMENSIONAL-SCALING HERSCHBACH DR-1993-DIMENSIONAL-SCALING-P7 HERSCHBACH DR-1996-INT-J-QUANTUM-CHEM-V57-P295 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1989-P-WELSCH-FD-CHEM-RES-V32-P95 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 HERSHBACH DR-1987-FARADAY-DISC-CHEM-SO-V84-P465 HIKAMI S-1979-J-PHYS-A-MATH-GEN-V12-P759 HOLAS A-1991-J-PHYS-A-MATH-GEN-V24-P4249 IKHDAIR SM-1993-Z-PHYS-D-ATOM-MOL-CL-V28-P1 IMBO T-1984-PHYS-LETT-A-V105-P183 IMBO T-1984-PHYS-REV-D-V29-P1669 IMBO TD-1985-PHYS-REV-LETT-V54-P2184 JAMEEL M-1986-J-PHYS-A-MATH-GEN-V19-P1967 JEVICKI A-1980-NUCL-PHYS-B-V171-P362 KAIS S-1995-J-CHEM-PHYS-V102-P7472 KAIS S-1994-J-CHEM-PHYS-V100-P4367 KAIS S-1993-J-CHEM-PHYS-V99-P417 KAIS S-1993-J-CHEM-PHYS-V99-P5184 KAIS S-1993-J-CHEM-PHYS-V98-P3990 KAIS S-1991-J-CHEM-PHYS-V95-P9028 KAIS S-1989-J-CHEM-PHYS-V91-P7791 KAIS S-1994-J-PHYS-CHEM-US-V98-P11015 KAIS S-1993-J-PHYS-CHEM-US-V97-P2453 KAIS S-1996-NATO-ASI-3-HIGH-TECH-V8-P55 KARNAKOV BM-1994-SOV-PHYS-JETP-V79-P534 KAUSHAL RS-1984-LETT-NUOVO-CIMENTO-V41-P434 KELLMAN ME-1994-PHYS-REV-LETT-V73-P2543 KELLMAN ME-1985-PHYS-REV-LETT-V55-P1738 KOSTELECKY VA-1985-PHYS-REV-D-V32-P2627 KUDINOV AV-1982-CZECH-J-PHYS-B-V32-P556 KUDINOV AV-1983-THEOR-MATH-PHYS+-V56-P871 KVENTSEL GF-1981-PHYS-REV-A-V24-P2299 LAI CH-1987-J-MATH-PHYS-V28-P1801 LIN CD-1986-ADV-ATOM-MOL-PHYS-V22-P77 LIN CD-1995-PHYS-REP-V257-P1 LIN CD-1984-PHYS-REV-A-V29-P1019 LIN CD-1993-REV-FUNDAMENTAL-PROC-P357 LOESER JG-1994-J-CHEM-PHYS-V100-P5036 LOESER JG-1991-J-CHEM-PHYS-V95-P4525 LOESER JG-1987-J-CHEM-PHYS-V86-P2114 LOESER JG-1987-J-CHEM-PHYS-V86-P3512 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1986-J-CHEM-PHYS-V84-P3882 LOESER JG-1986-J-CHEM-PHYS-V84-P3893 LOESER JG-1985-J-PHYS-CHEM-US-V89-P3444 LOESER JG-1996-NATO-ASI-3-HIGH-TECH-V8-P33 LOPEZCABRERA M-1993-J-PHYS-CHEM-US-V97-P2467 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 LOUCK JD-1960-J-MOL-SPECTROSCOPY-V4-P285 LOUCK JD-1960-J-MOL-SPECTROSCOPY-V4-P334 LOUCK JD-1960-J-MOL-SPECTRY-V4-P298 MALUENDES SA-1986-PHYS-REV-D-V34-P1835 MIRAMONTES JL-1984-NUOVO-CIMENTO-B-V84-P10 MLODINOW LD-1981-ANN-PHYS-NEW-YORK-V131-P1 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MOELOUT MO-COMMUNICATION MORALES DA-1989-CHEM-PHYS-LETT-V161-P253 MORALES DA-1996-INT-J-QUANTUM-CHEM-V57-P7 MORENO G-1986-J-PHYS-A-V19-P3707 MORENO G-1984-J-PHYS-B-AT-MOL-OPT-V17-P21 MORENO G-1987-PHYS-REV-A-V35-P2722 MORGAN JD-1993-DIMENSIONAL-SCALING-P336 MORGAN JD-1993-DIMENSIONAL-SCALING-P354 MUR VD-1987-JETP-LETT+-V45-P410 MUR VD-1990-SOV-J-NUCL-PHYS+-V51-P249 MUR VD-1988-SOV-J-NUCL-PHYS+-V47-P444 MUR VD-1990-SOV-PHYS-JETP-V70-P975 MUR VD-1990-ZH-EKSP-TEOR-FIZ+-V97-P32 MUSTAFA O-1993-J-QUANT-SPECTROSC-RA-V49-P65 NANOPOULOS DV-1994-RIV-NUOVO-CIMENTO-V17-P1 NIETO MM-1979-AM-J-PHYS-V47-P1067 PAGNAMENTA A-1986-PHYS-REV-D-V34-P3528 PANJA MM-1990-PHYS-REV-A-V42-P106 PANJA MM-1988-PHYS-REV-A-V38-P3937 PAPP E-1988-PHYS-REV-A-V38-P2158 PAPP E-1987-PHYS-REV-A-V36-P3550 POPOV VS-1994-JETP-LETT+-V59-P158 POPOV VS-1985-JETP-LETT+-V41-P439 POPOV VS-1996-NATO-ASI-3-HIGH-TECH-V8-P149 POPOV VS-1994-PHYS-LETT-A-V193-P159 POPOV VS-1994-PHYS-LETT-A-V193-P165 POPOV VS-1993-PHYS-LETT-A-V173-P63 POPOV VS-1993-PHYS-LETT-A-V172-P193 POPOV VS-1991-PHYS-LETT-A-V157-P185 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 POPOV VS-1991-YAD-FIZ-V54-P1582 POPOV VS-1986-YAD-FIZ-V44-P1103 ROST JM-1993-DIMENSIONAL-SCALING-P471 ROST JM-1991-J-PHYS-B-AT-MOL-OPT-V24-P2455 ROST JM-1991-J-PHYS-B-AT-MOL-OPT-V24-P4293 ROST JM-1993-J-PHYS-CHEM-US-V97-P2461 ROST JM-1992-PHYS-REV-A-V46-P2410 ROY B-1987-J-PHYS-A-MATH-GEN-V20-P3051 ROY B-1986-PHYS-REV-A-V34-P5108 ROYCHOUDHURY R-1989-PHYS-REV-A-V39-P5523 ROYCHOUDHURY R-1988-PHYS-REV-A-V37-P2309 RUDNICK J-1987-SCIENCE-V237-P384 SCHULTZ DR-1994-PHYS-REV-A-V50-P1348 SCHWARTZ C-1961-PHYSICAL-REVIEW-V123-P1700 SEVER R-1988-PHYS-REV-A-V37-P3158 SEVER R-1987-PHYS-REV-A-V36-P1045 SEVER R-1987-PHYS-REV-A-V35-P2725 SINHAROY M-1984-J-PHYS-A-MATH-GEN-V17-PL687 STEPANOV SS-1991-ZH-EKSP-TEOR-FIZ+-V100-P415 SUKHATME U-1983-PHYS-REV-D-V28-P418 SUKHATME UP-1986-PHYS-REV-D-V33-P1166 SUNG SM-1993-J-PHYS-CHEM-US-V97-P2479 SUVERNEV AA-IN-PRESS-CHEM-PHYS-L SUVERNEVV AA-UNPUB TALMAN JD-1968-SPEICAL-FUNCTIONS-GR TAN AL-1993-DIMENSIOAL-SCALING-C-P230 TANG AZ-1987-PHYS-REV-A-V35-P911 TRAYNOR CA-1993-J-PHYS-CHEM-US-V97-P2464 TSIPIS CA-1996-NATO-ADV-SCI-I-SERIE-V8 VAINBERG VM-1993-DIMENSIONAL-SCALING-P217 VAINBERG VM-1987-JETP-LETT+-V46-P225 VAINBERG VM-1986-JETP-LETT+-V44-P9 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470 VAINBERG VM-1988-TEOR-MAT-FIZ-V74-P399 VAINBERG VM-1987-ZH-EKSP-TEOR-FIZ+-V66-P258 VANDERMERWE PD-1985-J-CHEM-PHYS-V82-P5293 VANDERMERWE PD-1984-J-CHEM-PHYS-V81-P5976 VANDERMERWE PD-1989-PHYS-REV-A-V40-P1785 VANDERMERWE PD-1986-PHYS-REV-A-V34-P3452 VANDERMERWE PDT-1987-PHYS-REV-A-V36-P3446 VARSHNI YP-1989-PHYS-REV-A-V40-P2180 VARSHNI YP-1988-PHYS-REV-A-V38-P1595 VARSHNI YP-1987-PHYS-REV-A-V36-P3009 WATSON DK-1996-NATO-ASI-3-HIGH-TECH-V8-P83 WEYL H-1939-CLASSICAL-GROUPS WITTEN E-1980-NATO-ADV-STUDY-I-B-V59 WITTEN E-1980-PHYS-TODAY-V33-P38 YAFFE LG-1983-PHYS-TODAY-V36-P50 YAFFE LG-1982-REV-MOD-PHYS-V54-P407 YANEZ RJ-1994-PHYS-REV-A-V50-P3065 ZENG GJ-1994-PHYS-REV-A-V50-P4373 ZHEN Z-1993-DIMENSIONAL-SCALING-P83 ZHEN Z-1993-DIMENSIONAL-SCALING-P429
Source item page count:	16
Publication Date:	FEB
IDS No.:	169YW
29-char source abbrev:	PHYS REV A

Record 6 of 74
Author(s):	Carzoli JC; Dunn M; Watson DK
Title:	Singly and doubly excited states of the D-dimensional helium atom
Source:	PHYSICAL REVIEW A 1999, Vol 59, Iss 1, pp 182-187
No. cited references:	38
Addresses:	Carzoli JC, Univ Oklahoma, Dept Phys & Astron, Norman, OK 73019 USA. Univ Oklahoma, Dept Phys & Astron, Norman, OK 73019 USA.
KeywordsPlus:	ANGULAR-MOMENTUM STATES; LARGE-N EXPANSIONS; 1/D EXPANSION; POTENTIAL SCATTERING; PERTURBATION-THEORY; QUANTUM-MECHANICS; INTERDIMENSIONAL DEGENERACIES; VARIABLE DIMENSIONALITY; SCHRODINGER-EQUATION; 2-ELECTRON ATOMS
Abstract:	Large-order dimensional perturbation theory (DPT) has been used to study the ground and a number of excited states of two-electron atoms for the case L=0. Here we present an application of recent work generalizing DPT to any higher angular-momentum state. In this work we begin the investigation of P-o states, presenting results for the energies of some of the lowest-lying states and discuss the analytic structure of these energies as functions of 1/D. We also obtain energies of corresponding D-o states with almost no additional effort by making use of interdimensional degeneracies with the P-o states. [S1050-2947(98)06512-3].
Cited references:	BAKER GA-1981-PADE-APPROXIMANTS-1-V13 BELOV AA-1989-THEOR-MATH-PHYS+-V81-P1294 BELOV AA-1990-ZH-EKSP-TEOR-FIZ+-V98-P25 BENDER CM-1982-PHYS-REV-A-V25-P1305 BHATIA AK-1972-PHYS-REV-A-V6-P2498 BOLLE D-1984-PHYS-REV-A-V30-P1279 BOTTCHER C-1994-PHYS-REV-A-V49-P1714 BOYA LJ-1994-PHYS-REV-A-V50-P4397 CHATTERJEE A-1990-PHYS-REP-V186-P249 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DOREN DJ-1986-PHYS-REV-A-V34-P2665 DUNN M-1996-ANN-PHYS-NEW-YORK-V251-P266 DUNN M-1996-ANN-PHYS-NEW-YORK-V251-P319 DUNN M-1996-FEW-BODY-SYST-V21-P187 DUNN M-1994-J-CHEM-PHYS-V101-P5987 DUNN M-1993-J-PHYS-CHEM-US-V97-P2457 GANGYOPADHYAY RS-1985-PHYS-REV-D-V32-P3312 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GONZALEZ A-1993-J-PHYS-B-AT-MOL-OPT-V26-P1253 GOODSON DZ-1991-PHYS-REV-A-V44-P97 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1993-DIMENSIONAL-SCALING HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 KAIS S-1993-J-PHYS-CHEM-US-V97-P2453 KONO A-1986-PHYS-REV-A-V34-P1727 KVENTSEL GF-1981-PHYS-REV-A-V24-P2299 LOESER JG-1991-J-CHEM-PHYS-V95-P4525 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 POPOV VS-1993-DIMENSIONAL-SCALING-P217 POPOV VS-1994-PHYS-LETT-A-V193-P165 POPOV VS-1987-PHYS-LETT-A-V124-P77 SCHULTZ DR-1994-PHYS-REV-A-V50-P1348 SINHAROY M-1984-J-PHYS-A-MATH-GEN-V17-PL687 SUKHATME UP-1986-PHYS-REV-D-V33-P1166 SUVERNEV AA-1997-CHEM-PHYS-LETT-V269-P177 TSIPIS CA-1996-NEW-METHODS-QUANTUM-V8 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470
Source item page count:	6
Publication Date:	JAN
IDS No.:	158JD
29-char source abbrev:	PHYS REV A

Record 7 of 74
Author(s):	Walkup JR; Dunn M; Watson DK; Germann TC
Title:	Avoided crossings of diamagnetic hydrogen as functions of magnetic field strength and angular momentum
Source:	PHYSICAL REVIEW A 1998, Vol 58, Iss 6, pp 4668-4682
No. cited references:	85
Addresses:	Walkup JR, Univ Oklahoma, Dept Phys & Astron, Norman, OK 73019 USA. Univ Oklahoma, Dept Phys & Astron, Norman, OK 73019 USA. Univ Calif Los Alamos Natl Lab, Theoret Div T 11, Los Alamos, NM 87545 USA.
KeywordsPlus:	DIMENSIONAL PERTURBATION-THEORY; CIRCULAR RYDBERG STATES; LARGE-N EXPANSIONS; POTENTIAL SCATTERING; DENSITY FUNCTIONALS; EXCEPTIONAL POINTS; 1/D EXPANSION; WAVE-PACKETS; ATOM; SPECTRA
Abstract:	The energy levels of diamagnetic hydrogen as a function of two independent parameters, magnetic field strength B, and angular momentum m, are examined. Avoided crossings appear between these energy levels as either parameter is varied while the other is held fixed. These avoided crossings are directly related to degeneracies (Fermi resonances) occurring at zeroth order in perturbation theory. The mathematical basis of these degeneracies are the square-root branch points that connect the energy levels. It is found that the locations of avoided crossings in either constant-B or constant-in spectra can be predicted by visually scanning the locations of these branch points in the complex-delta plane, where delta= 1/(2 + 2 \m\) is the perturbation parameter used in this research. [S1050-2947(98)07111-X].
Cited references:	ARFKEN G-1985-MATH-METHODS-PHYSICI-P377 AVERBUKH IS-1989-PHYS-LETT-A-V139-P449 BELOV AA-1990-SOV-PHYS-JETP-V71-P12 BENDER CM-1978-ADV-MATH-METHODS-SCI-PCH8 BENDER CM-1982-PHYS-REV-A-V25-P1305 BERLIN TH-1952-PHYS-REV-V86-P821 BOHM A-1986-QUANTUM-ECH-FDN-APPL-PCH21 BOLLE D-1984-PHYS-REV-A-V30-P1279 BOYA LJ-1994-PHYS-REV-A-V50-P4397 BRANDI HS-1975-PHYS-REV-A-V11-P1835 BRAUN PA-1993-J-PHYS-B-AT-MOL-OPT-V26-P3739 BRAY AJ-1974-J-PHYS-A-MATH-GEN-V7-P2144 CACCIANI P-1992-J-PHYS-B-AT-MOL-OPT-V25-P1991 CHATTERJEE A-1990-PHYS-REP-V186-P249 CHEN L-1993-J-PHYS-B-AT-MOL-OPT-V26-PL437 DAI CM-1991-PHYSICA-B-V172-P455 DELANDE D-1991-CHAOS-QUANTUM-PHYSIC DELANDE D-1986-COMMENTS-AT-MOL-PHYS-V19-P35 DELANDE D-1988-EUROPHYS-LETT-V5-P303 DELANDE D-1991-PHYS-REV-LETT-V66-P3237 DUNN M-1996-J-CHEM-PHYS-V104-P9870 DUNN M-1994-J-CHEM-PHYS-V101-P5987 FASSBINDER P-1996-PHYS-REV-A-V53-P2135 FERMI E-1931-Z-PHYSIK-V71-P250 FERRELL RA-1974-PHYS-REV-A-V9-P846 FRIEDICH H-1991-THEORETICAL-ATOMIC-P FRIEDRICH H-1989-PHYS-REP-V183-P37 FRIEDRICH H-1990-THEORETICAL-ATOMIC-P GALLAGHER TF-1988-REP-PROG-PHYS-V51-P143 GANGYOPADHYAY RS-1985-PHYS-REV-D-V32-P3312 GARSTANG RH-1977-REP-PROG-PHYS-V40-P105 GAY JC-1991-AT-MOL-PHYS-V25-P185 GAY JC-1985-ATOMIC-EXCITATION-RE GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GERMANN TC-1995-PHYS-REV-LETT-V74-P658 GOLDBERG J-1991-J-PHYS-A-MATH-GEN-V24-P2785 GOLDSCHMIDT YY-1993-NUCL-PHYS-B-V393-P507 GREENSTEIN JL-1982-ASTROPHYS-J-V252-P285 HASEGAWA H-1969-PHYSICS-SOLIDS-INTEN HASEGAWA H-1989-PROG-THEOR-PHYS-SUPP-V98-P198 HEISS WD-1991-J-MATH-PHYS-V32-P3003 HEISS WD-1990-J-PHYS-A-MATH-GEN-V23-P1167 HERSCHBACH DR-1992-DIMENSIONAL-SCALING HERZBERG G-1945-MOLECULAR-SPECTRA-MO-V2-P215 HULET RG-1983-PHYS-REV-LETT-V51-P1430 IU CH-1991-PHYS-REV-LETT-V66-P145 IU CH-1989-PHYS-REV-LETT-V63-P1133 KAIS S-1993-J-CHEM-PHYS-V99-P417 KAIS S-1993-J-PHYS-CHEM-US-V97-P2453 KLEPPNER D-1983-RYDBERG-STATES-ATOMS KOTZE AA-1994-J-PHYS-A-MATH-GEN-V27-P3059 KVENTSEL GF-1981-PHYS-REV-A-V24-P2299 LANDAU L-1932-PHYSIK-Z-SOWJETUNION-V2-P46 LANDAU LD-1977-QUANTUM-MECH LIANG J-1986-PHYS-REV-A-V33-P4437 MAIN J-1994-J-PHYS-B-AT-MOL-OPT-V27-P2835 MAIN J-1986-PHYS-REV-LETT-V56-P2594 MARCH NH-1985-J-MATH-PHYS-V26-P554 MARCH NH-1986-PHYS-REV-A-V34-P5106 MARCH NH-1984-PHYS-REV-A-V30-P2936 MAVROIDES JG-1972-OPTICAL-PROPERTIES-S PARKER J-1986-PHYS-REV-LETT-V56-P716 POPOV VS-1994-PHYS-LETT-A-V193-P165 POPOV VS-1990-PHYS-LETT-A-V149-P418 RAMDAS AK-1981-REP-PROG-PHYS-V44-P1297 ROBNIK M-1977-J-PHYS-A-V14-P105 RUDNICK J-1987-SCIENCE-V237-P384 SERGEEV AV-COMMUNICATION SERRA P-1997-PHYS-REV-A-V55-P238 SINHAROY M-1984-J-PHYS-A-MATH-GEN-V17-PL687 SOLOVYOV EA-1981-ZH-EKSP-TEOR-FIZ+-V81-P1681 STANLEY HE-1968-PHYS-REV-V176-P718 STILLMAN GE-1971-SOLID-STATE-COMMUN-V9-P2245 SUKHATME UP-1986-PHYS-REV-D-V33-P1166 SUVERNEV AA-1997-CHEM-PHYS-LETT-V269-P177 TSIPIS CA-1996-NEW-METHODS-QUANTUM-V8 VALONE SM-1994-INT-J-QUANTUM-CHEM-V49-P591 WALKUP JR-UNPUB WANG QL-1991-PHYS-REV-A-V44-P1874 WATANABE S-1991-PHYS-REV-LETT-V67-P3227 WELCH GR-1989-PHYS-REV-LETT-V62-P893 WINTGEN D-1986-J-PHYS-B-AT-MOL-OPT-V19-P1261 WUNNER G-1981-PHYS-LETT-A-V247-P374 WUNNER G-1980-PHYS-LETT-A-V79-P159
Source item page count:	15
Publication Date:	DEC
IDS No.:	145CD
29-char source abbrev:	PHYS REV A

Record 8 of 74
Author(s):	Mur VD; Karnakov BM; Popov VS
Title:	Relativistic version of the imaginary-time formalism
Source:	JOURNAL OF EXPERIMENTAL AND THEORETICAL PHYSICS 1998, Vol 87, Iss 3, pp 433-444
No. cited references:	38
Addresses:	Mur VD, Moscow Engn Phys Inst, Moscow 115409, Russia. Moscow Engn Phys Inst, Moscow 115409, Russia. Inst Theoret & Expt Phys, Moscow 117218, Russia.
KeywordsPlus:	IONIZATION; FIELD
Abstract:	A relativistic version of the quasiclassical imaginary-time formalism is developed. It permits calculation of the tunneling probability of relativistic particles through potential barriers, including barriers lacking spherical symmetry. Application of the imaginary-time formalism to concrete problems calls for finding subbarrier trajectories which are solutions of the classical equations of motion, but with an imaginary time (and thus cannot be realized in classical mechanics). The ionization probability of an s level, whose binding energy can be of the order of the rest energy, under the action of electric and magnetic fields of different configuration is calculated using the imaginary-time formalism. Besides the exponential factor, the Coulomb and pre-exponential factors in the ionization probability are calculated. The Hamiltonian approach to the tunneling of relativistic particles is described briefly. Scrutiny of the ionization of heavy atoms by an electric field provides an additional argument against the existence of the "Unruh effect.'' (C) 1998 American Institute of Physics. [S1063-7761(98)00409-0].
Cited references:	AGAEV SS-1982-SOV-J-NUCL-PHYS+-V36-P599 ANDREEV SP-1985-JETP-LETT+-V42-P190 BARGMANN V-1959-PHYS-REV-LETTERS-V2-P435 BATYGIN VV-1964-PROBLEMS-ELECTRODYNA BAZ AI-1969-SCATTERING-REACTIONS BELINSKII VA-1998-JETP-LETT+-V67-P96 BIRRELL ND-1982-QUANTUM-FIELDS-CURVE DAVIES PCW-1975-J-PHYS-A-MATH-GEN-V8-P609 DEMKOV YN-1964-ZH-EKSP-TEOR-FIZ-V47-P918 DRUKAREV GF-1971-ZH-EKSP-TEOR-FIZ-V61-P956 FULLING SA-1973-PHYS-REV-D-V7-P2850 GINZBURG VL-1987-USP-FIZ-NAUK+-V153-P633 GREINER W-1985-QUANTUM-ELECTRODYNAM ITZYKSON C-1980-QUANTUM-FIELD-THEORY-V1 KARNAKOV BM-1997-JETP-LETT+-V65-P405 LANDAU LD-1975-CLASSICAL-THEORY-FIE LANDAU LD-1977-QUANTUM-MECH-NONRELA MARINOV MS-1977-FORTSCHR-PHYS-V25-P373 NIKISHOV AI-1988-SOV-PHYS-JETP-V67-P1313 PERELOMOV AM-1967-SOV-PHYS-JETP-V25-P336 PERELOMOV AM-1967-ZH-EKSP-TEOR-FIZ+-V24-P207 PIEPER W-1969-Z-PHYS-V218-P327 POPOV VS-1970-JETP-LETT-V11-P162 POPOV VS-1997-JETP-LETT+-V66-P229 POPOV VS-1996-JETP-LETT+-V63-P417 POPOV VS-1997-PHYS-LETT-A-V229-P306 POPOV VS-1971-SOV-J-NUCL-PHYS-V12-P235 POPOV VS-1998-SOV-PHYS-JETP-V86-P860 POPOV VS-1967-ZH-EKSP-TEO-V53-P331 POPOV VS-1971-ZH-EKSP-TEOR-FIZ+-V61-P1334 RADTSIG AA-1986-PARAMETERS-ATOMS-ATO RINDLER W-1966-AM-J-PHYS-V34-P1174 SCHWINGER J-1951-PHYS-REV-V82-P664 SMYTHE WR-1950-STATIC-DYNAMIC-ELECT UNRUH WG-1976-PHYS-REV-D-V14-P870 VANYASHIN VS-1965-SOV-PHYS-JETP-V21-P375 ZELDOVICH YB-1986-JETP-LETT-V43-P523 ZELDOVICH YB-1971-USP-FIZ-NAUK-V105-P403
Source item page count:	12
Publication Date:	SEP
IDS No.:	129EK
29-char source abbrev:	J EXP THEOR PHYS

Record 9 of 74
Author(s):	Slobodenyuk VA
Title:	Potentials with convergent Schwinger-DeWitt expansion
Source:	INTERNATIONAL JOURNAL OF THEORETICAL PHYSICS 1998, Vol 37, Iss 6, pp 1753-1771
No. cited references:	22
Addresses:	Slobodenyuk VA, Ulyanovsk State Univ, Phys Tech Dept, Ulyanovsk 432700, Russia. Ulyanovsk State Univ, Phys Tech Dept, Ulyanovsk 432700, Russia.
KeywordsPlus:	EVOLUTION OPERATOR KERNEL; PERTURBATION-THEORY; BEHAVIOR; SERIES
Abstract:	Convergence of the Schwinger-DeWitt expansion for the evolution operator kernel for special class of potentials is studied. It is shown that this expansion, which is in the general case asymptotic, converges for the potentials considered (widely used, in particular, in one-dimensional many-body problems), and that convergence takes place only for definite discrete values of the coupling constant. For other values of the charge, a divergent expansion determines the kernels having essential singularity at the origin (beyond the usual delta-function). If one considers only this class of potentials, then one can avoid many problems connected with asymptotic expansions, and one gets a theory with discrete values of the coupling constant that is in correspondence with the discreteness of charge in nature. This approach can be applied to quantum field theory.
Cited references:	BARVINSKY AO-1995-J-MATH-PHYS-V36-P30 BENDER CM-1971-PHYS-REV-D-V7-P1620 BENDER CM-1969-PHYSICAL-REVIEW-V184-P1231 BENDER CM-1971-PHYSICAL-REVIEW-LETT-V27-P461 CALOGERO F-1975-LETT-NUOVO-CIMENTO-V13-P383 DEWITT BS-1965-DYNAMICAL-THEORY-GRO DEWITT BS-1975-PHYS-REP-C-V19-P297 HALLIDAY IG-1980-PHYS-REV-D-V21-P1529 KAZAKOV DI-1980-FORTSCHR-PHYS-V28-P465 LIPATOV LN-1977-ZH-EKSP-TEOR-FIZ+-V72-P411 OLSHANETSKY AO-1983-PHYS-REP-V94-P315 OSBORN TA-1983-J-MATH-PHYS-V24-P1093 POPOV VS-1992-ZH-EKSP-TEOR-FIZ+-V102-P1453 SCHWINGER J-1951-PHYS-REV-V82-P64 SISSAKIAN AN-1992-Z-PHYS-C-PART-FIELDS-V54-P263 SLOBODENYUK VA-1996-MOD-PHYS-LETT-A-V11-P1729 SLOBODENYUK VA-1996-THEOR-MATH-PHYS+-V109-P1302 SLOBODENYUK VA-1995-THEOR-MATH-PHYS+-V105-P1387 SLOBODENYUK VA-1993-Z-PHYS-C-PART-FIELDS-V58-P575 SUTHERLAND B-1972-PHYS-REV-A-V5-P1372 SUTHERLAND B-1971-PHYS-REV-A-V4-P2019 USHVERIDZE AG-1983-YAD-FIZ-V38-P798
Source item page count:	19
Publication Date:	JUN
IDS No.:	117RB
29-char source abbrev:	INT J THEOR PHYS

Record 10 of 74
Author(s):	Popov VS; Karnakov BM; Mur VD
Title:	Ionization of atoms in electric and magnetic fields and the imaginary time method
Source:	JOURNAL OF EXPERIMENTAL AND THEORETICAL PHYSICS 1998, Vol 86, Iss 5, pp 860-874
No. cited references:	56
Addresses:	Popov VS, Inst Theoret & Expt Phys, Moscow 117259, Russia. Inst Theoret & Expt Phys, Moscow 117259, Russia. Tech Univ, Moscow Engn Phys Inst, Moscow 115409, Russia.
KeywordsPlus:	ORDER PERTURBATION-THEORY; HYDROGEN-ATOM; STARK RESONANCES; RYDBERG ATOMS; 1/N-EXPANSION
Abstract:	A semiclassical theory is developed for the ionization of atoms and negative ions in constant, uniform electric and magnetic fields, including the Coulomb interaction between the electron and the atomic core during tunneling. The case of crossed fields (Lorentz ionization) is examined specially, as well as the limit of a strong magnetic field. Analytic equations are derived for arbitrary fields E and H that are weak compared to the characteristic intraatomic fields. The major results of this paper are obtained using the ''imaginary time" method (ITM), in which tunneling is described using the classical equations of motion but with purely imaginary "time." The possibility of generalizing the ITM to the relativistic case, as well as to states with nonzero angular momentum, is pointed out. (C) 1998 American Institute of Physics. [S1063-7761(98)00405-3].
Cited references:	ALLILUEV SP-1979-PHYS-LETT-A-V73-P103 ALLILUEV SP-1982-SOV-PHYS-JETP-V55-P46 ALLILUEV SP-1993-ZH-EKSP-TEOR-FIZ+-V104-P3569 ANDREEV SP-1985-JETP-LETT+-V42-P190 ANDREEV SP-1983-JETP-LETT+-V37-P187 ANDREEV SP-1984-SOV-PHYS-JETP-V59-P506 ANDREEV SP-1985-TEOR-MAT-FIZ-V64-P287 BEKENSTEIN JD-1969-PHYS-REV-V188-P130 CHU MC-1984-PHYS-REV-A-V29-P675 DAMBURG RJ-1976-J-PHYS-B-AT-MOL-OPT-V9-P3149 DAVYDOV AS-1988-SOLID-STATE-THEORY DEMKOV YN-1988-ZERO-RANGE-POTENTIAL DEMKOV YN-1964-ZH-EKSP-TEOR-FIZ-V47-P918 DEMKOV YN-1969-ZHETF-V57-P1431 DRUKAREV GF-1971-SOV-PHYS-JETP-V34-P509 FERNANDEZ FM-1996-PHYS-REV-A-V54-P1206 FEYNMAN RP-1965-QUANTUM-MECH-PATH-IN FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 GORKOV LP-1967-SOV-PHYS-JETP-V26-P449 HERSCHBACH DR-1993-DIMENSIONAL-SCALING JOHNSON BR-1983-PHYS-REV-LETT-V51-P2280 KARNAKOV BM-1997-JETP-LETT+-V65-P405 KELDYSH LV-1964-ZH-EKSP-TEOR-FIZ+-V20-P1307 KOTOVA LP-1968-SOV-PHYS-JETP-V27-P616 LANDAU LD-1988-CLASSICAL-THEORY-FIE LANDAU LD-1974-QUANTUM-MECH-NONRELA LISITSA VS-1987-USP-FIZ-NAUK+-V153-P379 MAGARILL LI-1971-SOV-PHYS-JETP-V33-P97 MAIN J-1994-J-PHYS-B-AT-MOL-OPT-V27-P2835 MANAKOV NL-1986-ZH-EKSP-TEOR-FIZ+-V91-P404 MELEZHIK VS-1993-PHYS-REV-A-V48-P4528 NIKISHOV AI-1967-ZH-EKSP-TEO-V52-P223 NIKISHOV AI-1966-ZH-EKSP-TEOR-FIZ-V50-P255 PERELOMOV AM-1967-SOV-PHYS-JETP-V25-P336 PERELOMOV AM-1966-SOV-PHYS-JETP-V24-P207 PERELOMOV AM-1966-ZH-EKSP-TEOR-FIZ+-V23-P924 POPOV VS-1997-JETP-LETT+-V66-P229 POPOV VS-1996-JETP-LETT+-V63-P417 POPOV VS-1997-PHYS-LETT-A-V229-P306 POPOV VS-1993-PHYS-LETT-A-V173-P63 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 POPOV VS-1967-ZH-EKSP-TEO-V53-P331 RADTSIG AA-1968-PARAMETERS-ATOMS-ATO RAPOPORT LP-1978-THEORY-MANY-PHOTON-P SEIPP I-1997-ASTRON-ASTROPHYS-V318-P990 SILVERSTONE HJ-1978-PHYS-REV-A-V18-P1853 SMIRNOV BM-1965-SOV-PHYS-JETP-V22-P585 SOLOVEV EA-1983-ZH-EKSP-TEOR-FIZ+-V85-P109 TSIPIS CA-1996-NEW-METHODS-QUANTUM VAIBERG VM-1990-SOV-PHYS-JETP-V71-P470 VAINBERG VM-1986-JETP-LETT+-V44-P9 WANG JH-1995-PHYS-REV-A-V52-P4508 YAMABE T-1977-PHYS-REV-A-V16-P877 ZON BA-1971-SOV-PHYS-JETP-V34-P515
Source item page count:	15
Publication Date:	MAY
IDS No.:	107XQ
29-char source abbrev:	J EXP THEOR PHYS

Record 11 of 74
Author(s):	Huang SW; Goodson DZ; Lopez-Cabrera M; Germann TC
Title:	Large-order dimensional perturbation theory for diatomic molecules within the Born-Oppenheimer approximation
Source:	PHYSICAL REVIEW A 1998, Vol 58, Iss 1, pp 250-257
No. cited references:	50
Addresses:	Huang SW, So Methodist Univ, Dept Chem, Dallas, TX 75275 USA. So Methodist Univ, Dept Chem, Dallas, TX 75275 USA. Harvard Univ, Dept Chem, Cambridge, MA 02138 USA. Univ Calif Los Alamos Natl Lab, Theoret Div T11, Los Alamos, NM 87545 USA.
KeywordsPlus:	GROUND-STATE ENERGY; VARIABLE DIMENSIONALITY; 1/D EXPANSION; LIMIT; SERIES; ATOMS; H-2+; H2+; RENORMALIZATION; 1/N-EXPANSION
Abstract:	A renormalization of the D-dimensional Hamiltonian is developed to ensure that the large-D limit corresponds to a single well at any value of the internuclear distance R. This avoids convergence problems caused by a symmetry-breaking transition that is otherwise expected to occur when R is approximately equal to the equilibrium bond distance R-eq, With larger R giving a double well. This symmetry breaking has restricted the applicability of large-order perturbation theory in 1/D to cases where R is significantly less than R-eq. The renormalization greatly extends the range of R for which the large-order expansion can be summed. A numerical demonstration is presented for H-2(+). The 1/D expansions are summed using Pade-Borel approximants with modifications that explicitly model known singularity structure.
Cited references:	ARTECA GA-1990-LARGE-ORDER-PERTURBA-P126 ATAG S-1988-PHYS-REV-A-V37-P2280 AUSTIN EJ-1984-J-PHYS-A-MATH-GEN-V17-P367 BELOV AA-1990-ZH-EKSP-TEOR-FIZ+-V98-P25 BLEIL R-1995-J-CHEM-PHYS-V103-P6529 CIZEK J-1985-INT-J-QUANTUM-CHEM-S-V20-P65 COHEN JM-1996-INT-J-QUANTUM-CHEM-V59-P445 COULSON CA-1961-VALENCE DARBOUX MG-1878-J-MATH-V4-P377 DUNN M-1994-J-CHEM-PHYS-V101-P5987 DYSON FJ-1952-PHYS-REV-V85-P631 ELOUT MO-IN-PRESS-J-MATH-PHYS FEINBERG MJ-1971-J-CHEM-PHYS-V54-P1495 FRANTZ DD-1988-CHEM-PHYS-V126-P59 FRANTZ DD-1990-J-CHEM-PHYS-V92-P6668 FRANTZ DD-1989-PHYS-REV-A-V40-P1175 FRNTZ DD-QCMP071-IND-U-DEP-CH FROST AA-1956-J-CHEM-PHYS-V25-P1150 GERMANN TC-1994-COMPUT-PHYS-V8-P712 GOODSON DZ-1993-DIMENSIONAL-SCALING-P115 GOODSON DZ-1993-DIMENSIONAL-SCALING-P275 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1997-PHYS-REV-A-V55-P4155 GOODSON DZ-1992-PHYS-REV-A-V46-P5428 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1993-DIMENSIONAL-SCALING-P61 HERSCHBACH DR-1996-INT-J-QUANTUM-CHEM-V57-P295 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 KAIS S-1992-CHEM-PHYS-V161-P393 KAIS S-1991-J-CHEM-PHYS-V95-P9028 KAIS S-1994-J-PHYS-CHEM-US-V98-P11015 KILLINGBECK J-1981-J-PHYS-A-MATH-GEN-V14-P1005 LOESER JG-1996-NEW-METHODS-QUANTUM-P1 LOPEZ MM-1991-THESIS-U-MICHIGAN-P88 LOPEZCABRERA M-1993-J-PHYS-CHEM-US-V97-P2467 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MLODINOW LD-1982-PROGR-PARTICLE-NUCL-V8-P387 MUR VD-1990-ZH-EKSP-TEOR-FIZ+-V97-P32 NINHAM BW-1963-J-MATH-PHYS-V4-P679 PAULING L-1935-INTRO-QUANTUM-MECH POPOV VS-1994-PHYS-LETT-A-V193-P165 ROSEN N-1931-PHYS-REV-V38-P2099 ROST JM-1992-J-PHYS-CHEM-US-V97-P2461 SUNG SM-1992-J-PHYS-CHEM-US-V97-P2479 TELLER E-1970-PHYSICAL-CHEM-ADV-TR-V5-P35 VINETTE F-1991-J-MATH-PHYS-V32-P3392 WATSON DK-1995-PHYS-REV-A-V51-PR5 WENIGER EJ-1993-J-MATH-PHYS-V34-P571 YAFFE LG-1982-REV-MOD-PHYS-V54-P407
Source item page count:	8
Publication Date:	JUL
IDS No.:	ZZ998
29-char source abbrev:	PHYS REV A

Record 12 of 74
Author(s):	Vainberg VM; Gani VA; Kudryavtsev AE
Title:	High-order perturbation theory for the hydrogen atom in a magnetic field
Source:	JOURNAL OF EXPERIMENTAL AND THEORETICAL PHYSICS 1998, Vol 86, Iss 2, pp 305-311
No. cited references:	27
Addresses:	Vainberg VM, Inst Theoret & Expt Phys, Moscow 117259, Russia. Inst Theoret & Expt Phys, Moscow 117259, Russia.
Abstract:	The states of a hydrogen atom with principal quantum numbers n less than or equal to 3 in a constant uniform magnetic field H are studied. Coefficients in the expansion of the energy of these states in powers of H-2 up to the 75th order are obtained. Series for the energies of the states and the wave functions are summed to values of H on the order of the atomic magnetic field. A generalization of the moment method upon which these calculations are based can be used in other cases in which a hydrogen atom is perturbed by a potential with a polynomial dependence on the coordinates. (C) 1998 American Institute of Physics.
Cited references:	ADAMS BG-1980-PHYS-REV-A-V21-P1914 ADER JP-1983-PHYS-LETT-A-V97-P178 AHARONOV Y-1980-PHYS-REV-A-V22-P328 AHARONOV Y-1979-PHYS-REV-A-V20-P2245 ALLILUEV SP-1979-PHYS-LETT-A-V73-P103 ALLILUEV SP-1982-ZH-EKSP-TEOR-FIZ+-V82-P77 AVRON JE-1981-ANN-PHYS-NEW-YORK-V131-P73 BENDER CM-1982-PHYS-REV-A-V25-P1305 BENDER CM-1973-PHYS-REV-D-V7-P1620 CABIB D-1972-NUOVO-CIMENTO-B-V10-P185 CIZEK J-1982-INT-J-QUANTUM-CHEM-V21-P27 DOLGOV AD-1979-PHYS-LETT-B-V86-P185 ELETSKII VL-1980-DOKL-AKAD-NAUK-SSSR+-V250-P74 GALINDO A-1976-NUOVO-CIMENTO-B-V34-P155 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 JOHNSON BR-1983-PHYS-REV-LETT-V51-P2280 KILLINGBECK J-1978-PHYS-LETT-A-V65-P87 LISITSA VS-1987-USP-FIZ-NAUK+-V153-P379 PEKAR VS-1971-TEOR-MAT-FIZ-V9-P140 POLIKANOV VS-1967-ZH-EKSP-TEOR-FIZ+-V25-P882 POPOV VS-1996-JETP-LETT+-V63-P417 PRIVMAN V-1980-PHYS-REV-A-V22-P1833 SVENSON RJ-1972-J-CHEM-PHYS-V57-P1734 TURBINER AV-1982-Z-PHYS-A-HADRON-NUCL-V308-P111 TURBINER AV-1983-ZH-EKSP-TEOR-FIZ+-V84-P1329 WANG JH-1995-PHYS-REV-A-V52-P4508 ZIMAN J-1971-MODERN-QUANTUM-THEOR-PCH3
Source item page count:	7
Publication Date:	FEB
IDS No.:	ZD541
29-char source abbrev:	J EXP THEOR PHYS

Record 13 of 74
Author(s):	Slobodenyuk VA
Title:	Convergence of the Schwinger-DeWitt expansion for some potentials
Source:	INTERNATIONAL JOURNAL OF THEORETICAL PHYSICS 1998, Vol 37, Iss 1, pp 563-569
No. cited references:	13
Addresses:	Slobodenyuk VA, Ulyanovsk State Univ, Dept Tech Phys, Ulyanovsk 432700, Russia. Ulyanovsk State Univ, Dept Tech Phys, Ulyanovsk 432700, Russia.
KeywordsPlus:	EVOLUTION OPERATOR KERNEL
Abstract:	The time dependence of the evolution operator kernel for the Schrodinger equation has been studied with a help of the Schwinger-D-Witt expansion. For many of potentials this expansion is divergent. But there are nontrivial potentials for which the Schwinger-DeWitt expansion is convergent. These are, e.g., V = g/x(2), V = g/cosh(2)x, V = g/sinh(2)x, V = g/sin(2)x. For all of them the expansion is convergent when g = lambda(lambda - 1)/2 and lambda is integer. The theories with these potentials have no divergences and in this sense they are "good" potentials, in contrast to other ones. So it seems natural to pay special attention to these "good" potentials. Besides convergence, they have another interesting feature: convergence takes place only for discrete values of the charge g. Hence, in the theories of this class the charge is quantized.
Cited references:	BARVINSKY AO-1995-J-MATH-PHYS-V36-P30 BENDER CM-1969-PHYSICAL-REVIEW-V184-P1231 DEWITT BS-1965-DYNAMICAL-THEORY-GRO DEWITT BS-1975-PHYS-REP-C-V19-P297 LIPATOV LN-1977-ZH-EKSP-TEOR-FIZ+-V72-P411 OSBORN TA-1983-J-MATH-PHYS-V24-P1093 POPOV VS-1992-ZH-EKSP-TEOR-FIZ+-V102-P1453 SCHWINGER J-1951-PHYS-REV-V82-P664 SLOBODENYUK VA-1995-9570-IHEP SLOBODENYUK VA-1996-IN-PRESS-THEORETICAL-V109 SLOBODENYUK VA-1996-MOD-PHYS-LETT-A-V11-P1729 SLOBODENYUK VA-1995-THEOR-MATH-PHYS+-V105-P1387 SLOBODENYUK VA-1993-Z-PHYS-C-PART-FIELDS-V58-P575
Source item page count:	7
Publication Date:	JAN
IDS No.:	ZD912
29-char source abbrev:	INT J THEOR PHYS

Record 14 of 74
Author(s):	Slobodenyuk VA
Title:	On convergence of the Schwinger-De Witt expansion
Source:	MODERN PHYSICS LETTERS A 1997, Vol 12, Iss 37, pp 2889-2903
No. cited references:	14
Addresses:	Slobodenyuk VA, IN Ulyanov State Univ, Dept Tech Phys, L Tostogo Str 42, Ulyanovsk 432700, Russia. IN Ulyanov State Univ, Dept Tech Phys, Ulyanovsk 432700, Russia.
KeywordsPlus:	EVOLUTION OPERATOR KERNEL
Abstract:	The Schwinger-De Witt expansion for the evolution operator kernel of the Schrodinger equation is studied for convergence. It is established that divergence of this expansion which is usually implied for all continuous potentials, excluding those of the form V(q) = aq(2) + bq + c, takes place only if the coupling constant g is treated as an independent variable. But the expansion may be convergent for some kinds of potentials and for some discrete values of charge, if the latter is considered as fixed parameter. Class of such potentials is interesting because inside it the property of discreteness of the charge in nature is reproduced in theory in the natural way.
Cited references:	BARVINSKY AO-1995-J-MATH-PHYS-V36-P30 BENDER CM-1969-PHYSICAL-REVIEW-V184-P1231 DEWITT BS-1965-DYNAMICAL-THEORY-GRO DEWITT BS-1975-PHYS-REP-C-V19-P297 LIPATOV LN-1977-ZH-EKSP-TEOR-FIZ+-V72-P411 MARTIN A-1986-PHYS-REP-V134-P305 OSBORN TA-1983-J-MATH-PHYS-V24-P1093 POPOV VS-1992-ZH-EKSP-TEOR-FIZ+-V102-P1453 SCHWINGER J-1951-PHYS-REV-V82-P664 SLOBODENYUK VA-1995-9570-IHEP SLOBODENYUK VA-1996-MOD-PHYS-LETT-A-V11-P1729 SLOBODENYUK VA-1996-THEOR-MATH-PHYS+-V109-P1302 SLOBODENYUK VA-1995-THEOR-MATH-PHYS+-V105-P1387 SLOBODENYUK VA-1993-Z-PHYS-C-PART-FIELDS-V58-P575
Source item page count:	15
Publication Date:	DEC 7
IDS No.:	YM362
29-char source abbrev:	MOD PHYS LETT A

Record 15 of 74
Author(s):	Popov VS; Mur VD; Karnakov BM
Title:	The imaginary-time method for relativistic problems
Source:	JETP LETTERS 1997, Vol 66, Iss 4, pp 229-235
No. cited references:	17
Addresses:	Popov VS, INST THEORET & EXPT PHYS, MOSCOW 117218, RUSSIA. MOSCOW ENGN PHYS INST, MOSCOW 115409, RUSSIA.
Abstract:	A relativistic version of the imaginary-time method is presented. The method is used to calculate the probability w of ionization of a bound state by electric and magnetic fields of various configurations (including the case when the binding energy E-b is comparable to mc(2)). The formulas cover as limiting cases both the ionization of nonrelativistic bound systems (atoms and ions) and the case E-b=2mC(2), when w equals the probability of electron-positron pair production from the vacuum in the presence of a strong field. (C) 1997 American Institute of Physics.
Cited references:	ANDREEV SP-1985-JETP-LETT+-V42-P190 BARGMANN V-1959-PHYS-REV-LETTERS-V2-P435 DEMKOV YN-1965-SOVIET-PHYSICS-JETP-V20-P614 GREINER W-1985-QUANTUM-ELECTRODYNAM KARNAKOV BM-1997-JETP-LETT+-V65-P405 LANDAU LD-1988-CLASSICAL-THEORY-FIE LANDAU LD-1974-QUANTUM-MECHANICS MARINOV MS-1972-SOV-J-NUCL-PHYS+-V15-P702 PERELOMOV AM-1967-ZH-EKSP-TEOR-FIZ+-V24-P207 PIEPER W-1969-Z-PHYS-V218-P327 POPOV VS-1996-JETP-LETT+-V63-P417 POPOV VS-1997-PHYS-LETT-A-V225 POPOV VS-1972-SOV-J-NUCL-PHYS-V14-P673 POPOV VS-1968-SOV-PHYS-JETP-V26-P222 SCHWINGER J-1951-PHYS-REV-V82-P664 SCHWINGER J-1964-QUANTUM-ELECTRODYNAM ZELDOVICH YB-1970-SOV-PHYS-USP-V12-P235
Source item page count:	7
Publication Date:	AUG 25
IDS No.:	XY034
29-char source abbrev:	JETP LETT-ENGL TR

Record 16 of 74
Author(s):	Suvernev AA; Goodson DZ
Title:	Dimensional perturbation theory for vibration-rotation spectra of linear triatomic molecules
Source:	JOURNAL OF CHEMICAL PHYSICS 1997, Vol 107, Iss 11, pp 4099-4111
No. cited references:	70
Addresses:	Suvernev AA, SO METHODIST UNIV, DEPT CHEM, DALLAS, TX 75275.
KeywordsPlus:	EXCITED ROVIBRATIONAL STATES; LARGE-ORDER; SCHRODINGER-EQUATION; QUANTUM-MECHANICS; FLOPPY MOLECULES; 2-ELECTRON ATOMS; 1/N EXPANSION; EIGENVALUES; ENERGIES; OSCILLATORS
Abstract:	A very efficient large-order perturbation theory is formulated for the nuclear motion of a linear triatomic molecule. All coupling between vibration and rotation is included. To demonstrate the method, all of the experimentally observed rotational energies, with values of J almost up to 100, for the ground and first excited vibrational states of CO2 and for the ground vibrational states of N2O and of OCS are calculated. The perturbation expansions reported here are rapidly convergent. The perturbation parameter is D-1/2, where D is the dimensionality of space. Increasing D is qualitatively similar to increasing the angular momentum quantum number J. Therefore, this approach is especially suited for states with high rotational excitation. The computational cost of the method scales only in proportion to JN(nu)(5/3), where N-nu is the size of the vibrational basis set. (C) 1997 American Institute of Physics.
Cited references:	ALLEN HC-1963-MOL-VIB-ROTORS-P51 BACIC Z-1989-ANNU-REV-PHYS-CHEM-V40-P469 BELOV AA-1990-SOV-PHYS-JETP-V71-P12 BELOV AA-1988-SOV-PHYS-JETP-V67-P2413 BENDER CM-1978-ADV-MATH-METHODS-SCI-P89 BENDER CM-1973-PHYS-REV-D-V7-P1620 BOWMAN JM-1991-J-CHEM-PHYS-V94-P454 BOWMAN JM-1978-J-CHEM-PHYS-V68-P608 CARNEY GD-1978-ADV-CHEM-PHYS-V37-P305 CARTER S-1983-MOL-PHYS-V49-P745 CHANG J-1986-J-CHEM-PHYS-V84-P4997 CHATTERJEE A-1990-PHYS-REP-V186-P249 CHEDIN A-1979-J-MOL-SPECTROSC-V76-P430 CHEN CL-1985-J-CHEM-PHYS-V83-P1795 CIZEK J-1993-J-CHEM-PHYS-V99-P7331 COHEN JM-1996-INT-J-QUANTUM-CHEM-V59-P445 DUNN M-1996-ANN-PHYS-NEW-YORK-V251-P266 DUNN M-1996-J-CHEM-PHYS-V104-P9870 DUNN M-1994-J-CHEM-PHYS-V101-P5987 EDMONDS AR-1957-ANGULAR-MOMENTUM-QUA-P62 ESTES D-1986-MOL-PHYS-V59-P569 FRANTZ DD-1988-CHEM-PHYS-V126-P59 GERBER RB-1988-ADV-CHEM-PHYS-V70-P97 GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GONZALEZ A-1993-J-PHYS-B-AT-MOL-OPT-V26-P1253 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1997-PHYS-REV-A-V55-P4155 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 GOODSON DZ-1992-PHYS-REV-A-V46-P5428 HANDY NC-1987-MOL-PHYS-V61-P207 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1993-DIMENSIONAL-SCALING HERSCHBACH DR-1993-DIMENSIONAL-SCALING-P61 HERSCHBACH DR-1996-INT-J-QUANTUM-CHEM-V57-P295 HERZBERG G-1966-MOL-SPECTRA-MOL-STRU-V2-P276 HUCKEL W-1950-STRUCTURAL-CHEM-INOR-V1-P432 KAIS S-1993-J-CHEM-PHYS-V98-P3990 KAIS S-1996-NEW-METHODS-QUANTUM-P55 KILLINGBECK J-1981-J-PHYS-A-MATH-GEN-V14-P1005 KIVELSON D-1952-J-CHEM-PHYS-V20-P1575 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1996-NEW-METHODS-QUANTUM-P33 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 LOUCK J-1960-J-MOL-SPECTROSC-V3-P673 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MLODINOW LD-1982-PROGR-PARTICLE-NUCL-V8-P387 MORALES DA-1989-CHEM-PHYS-LETT-V161-P253 NAUTS A-1984-PHYS-REV-A-V30-P872 NIELSEN HH-1951-REV-MOD-PHYS-V23-P90 PAPOUSEK D-1982-MOL-VIBRATIONAL-ROTA-P57 PARLETT BN-1980-SYMMETRIC-EIGENVALUE-P119 POPOV VS-1994-PHYS-LETT-A-V193-P165 POPOV VS-1992-SOV-PHYS-JETP-V75-P787 ROTHMAN LS-1992-J-QUANT-SPECTROSC-RA-V48-P469 SIBERT EL-1988-J-CHEM-PHYS-V88-P4378 SUTCLIFFE BT-1982-CURRENT-ASPECTS-QUAN-P99 SUVERNEV AA-1997-CHEM-PHYS-LETT-V269-P177 SUVERNEV AA-1997-J-CHEM-PHYS-V106-P2681 TENNYSON J-1989-J-CHEM-PHYS-V91-P3815 TENNYSON J-1986-MOL-PHYS-V58-P1067 TENNYSON J-1990-PHILOS-T-ROY-SOC-A-V332-P329 TOWNES CH-1955-MICROWAVE-SPECTROSCO-P624 TSIPIS CA-1996-NEW-METHODS-QUANTUM VAINBERG VM-1986-JETP-LETT+-V44-P9 VAINBERG VM-1988-THEOR-MATH-PHYS+-V74-P269 VARSHALOVICH DA-1988-QUANTUM-THEORY-ANGUL-PCH4 WATSON DK-1995-PHYS-REV-A-V51-PR5 WILSON EB-1936-J-CHEM-PHYS-V4-P262 YAFFE LG-1982-REV-MOD-PHYS-V54-P407
Source item page count:	13
Publication Date:	SEP 15
IDS No.:	XW119
29-char source abbrev:	J CHEM PHYS

Record 17 of 74
Author(s):	Perrot F; Grimaldi A
Title:	Linear response of a magnetized electron gas: Application to the thermodynamics of aluminium
Source:	JOURNAL OF PHYSICS-CONDENSED MATTER 1997, Vol 9, Iss 32, pp 6845-6867
No. cited references:	68
Addresses:	Perrot F, CEA, CTR ETUD LIMEIL VALENTON, F-94195 VILLENEUVE ST GEO, FRANCE.
KeywordsPlus:	DENSITY-FUNCTIONAL THEORY; GROUND-STATE ENERGIES; HYDROGEN-ATOM; THOMAS-FERMI; ARBITRARY STRENGTH; EXCITED-STATES; LANDAU STATES; FIELD; SYSTEMS; TRANSITIONS
Abstract:	We first consider the three independent functions that describe the linear response to external perturbations of a non-interacting strongly magnetized electron gas. These functions are needed to build the interacting response to an external perturbation, even if it is purely scalar. The interacting response function is obtained in the local density approximation for the exchange and correlation energy functional E-xc(1)(n, omega). It is singular when the non-interacting Fermi level coincides with a Landau band edge. In addition, the numerical study of the effective local-field factor shows that the response function can also have poles in a region of densities and magnetic fields approximately defined by: r(s) > 3.5 and 0.3 greater than or equal to B/B-0 greater than or equal to 0.1, where B-0 is the reference magnetic held (1 atomic unit = 2.35 x 10(9) Gauss). Outside this region, we use the linear response theory applied to a model electron-ion interaction for an estimate of the equation of state of solid aluminium in the presence of strong magnetic fields up to B = B-0. The densities are in the range 0.8-1.5 times the normal density. The results show the importance of the changes induced by the magnetic field, in particular those associated with the localization of the charge density.
Cited references:	AMOVILLI C-1991-PHYS-REV-A-V43-P2528 BALLA K-1996-J-PHYS-A-MATH-GEN-V29-P6747 BANERJEE B-1974-PHYS-REV-D-V10-P2384 BARCZA S-1996-J-PHYS-A-MATH-GEN-V29-P6765 BEZCHASTNOV VG-1995-J-PHYS-B-AT-MOL-OPT-V28-P167 BEZCHASTNOV VG-1994-J-PHYS-B-AT-MOL-OPT-V27-P3349 BOEBINGER G-1996-PHYSICS-TODAY-JUN-P36 BOEBINGER G-1996-PHYSICS-TODAY-OCT-P11 BYLICKI M-1994-J-PHYS-B-AT-MOL-OPT-V27-P2741 CHAKRABORTY T-1992-COMMENTS-CONDENS-MAT-V16-P35 CHEN ZH-1992-PHYS-REV-A-V45-P1722 CHIU KW-1974-PHYS-REV-B-V9-P4724 CHUU DS-1993-PHYS-REV-A-V48-P4175 DELANDE D-1991-PHYS-REV-LETT-V66-P141 FELBER FS-1988-PHYS-FLUIDS-V31-P2053 GLASSER ML-1972-ANN-PHYS-NEW-YORK-V73-P1 GLASSER ML-1983-PHYS-REV-B-V28-P4387 GLOSSMAN MD-1988-J-PHYS-B-AT-MOL-OPT-V21-P411 GRADSHTEYN IS-1965-TABLES-INTEGRALS-SER GRAYCE CJ-1994-PHYS-REV-A-V50-P3089 GREENE MP-1969-PHYS-REV-V177-P1019 HEINE V-1964-PHIL-MAG-V9-P451 HEINE V-1965-PHILOSOPHICAL-MAG-V12-P529 JONES MD-1996-PHYS-REV-A-V54-P219 JONES W-1971-J-PHYS-C-V4-P1322 KADOMTSEV BB-1970-ZH-EKSP-TEOR-FIZ+-V31-P945 KAPPES U-1995-PHYS-REV-A-V51-P4542 KASTNER MA-1992-REV-MOD-PHYS-V64-P849 KRAVCHENKO YP-1996-PHYS-REV-A-V54-P287 KRAVCHENKO YP-1996-PHYS-REV-LETT-V77-P619 LAI D-1996-PHYS-REV-A-V53-P152 LANDAU LD-1980-COURSE-THEORETICAL-P LANDAU LD-1959-QUANTUM-MECHANICS LEHMANN H-1995-PURE-APPL-CHEM-V67-P457 LEVIN FS-1985-PHYS-REV-A-V32-P3285 LI S-1990-PHYS-REV-A-V41-P2344 LIBERMAN MA-1994-MEGAGAUSS-MAGNETIC-F-P271 LIBERMAN MA-1994-MEGAGAUSS-MAGNETIC-F-P281 LIBERMAN MA-1995-SOV-PHYS-USP-V38-P117 LIEB EH-1992-PHYS-REV-LETT-V69-P749 MIURA N-1994-MEGAGAUSS-MAGNETIC-F-P125 MUELLER RO-1971-PHYS-REV-LETT-V26-P1136 MUSTAFA O-1994-PHYS-REV-A-V50-P2926 NEUHAUSER D-1987-PHYS-REV-A-V36-P4163 NOZIERES P-1966-THEORY-QUANTUM-LIQUI ORTIZ G-1995-PHYS-REV-A-V52-PR3405 PAVLOV GG-1995-ASTROPHYS-J-V450-P883 PERROT F-1995-J-PHYS-CONDENS-MATT-V7-P654 POPOV VS-1996-JETP-LETT+-V63-P417 PRANGE RE-1990-QUANTUM-HALL-EFFECT RELOVSKY BM-1995-INT-J-QUANTUM-CHEM-V56-P825 RELOVSKY BM-1996-PHYS-REV-A-V53-P4068 RUDER H-1994-ATOMS-STRONG-MAGNETI SAINI S-1987-PHYS-REV-A-V36-P3556 SHERTZER J-1989-PHYS-REV-A-V39-P3833 SKJERVOLD JE-1984-PHYS-SCRIPTA-V29-P448 SKUDLARSKI P-1993-PHYS-REV-B-V48-P8547 SKUDLARSKI P-1992-PHYS-REV-LETT-V69-P949 THURNER G-1993-J-PHYS-B-AT-MOL-OPT-V26-P4719 TOMISHIMA Y-1982-J-PHYS-B-AT-MOL-OPT-V15-P2837 TOMISHIMA Y-1979-PROG-THEOR-PHYS-V62-P853 TOMISHIMA Y-1978-PROG-THEOR-PHYS-V59-P683 VIGNALE G-1992-PHYS-REV-B-V46-P10232 VIGNALE G-1988-PHYS-REV-B-V37-P10685 WANG JH-1995-PHYS-REV-A-V52-P4508 WUNNER G-1987-PHYS-SCRIPTA-V36-P291 YONEI K-1990-J-PHYS-SOC-JPN-V59-P3571 ZANG JX-1994-PHYS-REV-A-V50-P861
Source item page count:	23
Publication Date:	AUG 11
IDS No.:	XQ903
29-char source abbrev:	J PHYS-CONDENS MATTER

Record 18 of 74
Author(s):	Preobrazhenskii MA
Title:	Exact nonrelativistic expressions for the tensor for scattering of light by atoms
Source:	JOURNAL OF EXPERIMENTAL AND THEORETICAL PHYSICS 1997, Vol 84, Iss 3, pp 448-456
No. cited references:	22
Addresses:	Preobrazhenskii MA, VORENEZH STATE ACAD ARCHITECTURE & CIVIL ENGN, VORONEZH 394000, RUSSIA.
Abstract:	Exact nonrelativistic analytical expressions are derived for dipole two-photon transitions between arbitrary multiplets of the hydrogen atom and positive hydrogenlike ions. The result is expressed in terms of a single Gauss hypergeometric function and polynomials whose degrees increase linearly with the number of nodes of the bound states of the quantum system. The cross sections of elastic scattering of light by K- and L-shells of the hydrogen atom are given as an example. It is demonstrated that by expanding the discrete-spectrum wave functions in ultraspherical polynomials it is also possible to obtain analytical expressions of the cross sections of two-photon transitions between states described by the Simons model potential. The basis consisting of Chebyshev polynomials is shown to be the best expansion basis, and the coefficients of such an expansion are given for a broad range of parameters of the problem. Calculation of the polarizability of the SS-state of the rubidium atom is chosen as an example. Finally, the results are compared with the experimental data and the theoretical results of other researchers. (C) 1997 American Institute of Physics. (C) 1997 American Institute of Physics.
Cited references:	AKHIEZER AI-1974-QUANTUM-ELECTRODYNAM AMUSYA MY-1973-SOV-PHYS-JETP-V36-P468 BEIGMAN IL-1994-PHYS-REV-A-V49-P5883 BERGMAN IL-1991-SOV-PHYS-JETP-V73-P68 BONIN KD-1993-PHYS-REV-A-V47-P999 DELONE NB-1982-SOV-PHYS-JETP-V56-P1170 EPSTEIN IR-1970-J-CHEM-PHYS-V53-P1881 ERDELYI A-1953-HIGHER-TRANSCENDENTA GAVRILA M-1967-PHYS-REV-V163-P147 KELLY HP-1969-PHYS-REV-V182-P84 LANCZOS C-1956-APPLIED-ANAL MANAKOV NL-1976-J-PHYS-B-ATOM-MOL-PH-V10-P569 MANAKOV NL-1989-SOV-PHYS-JETP-V68-P451 MARINESCU M-1994-PHYS-REV-A-V49-P5103 MOORE CE-1950-488-NBS PREOBRAZHENSKII MA-1993-LASER-PHYS-V3-P688 PREOBRAZHENSKII MA-1994-OPT-SPECTROSC-V77-P494 RAPOPORT LP-1978-THEORY-MULTIPHOTON-P RITUS VT-1967-ZH-EKSP-TEOR-FIZ+-V24-P1041 SOBELMAN II-1973-INTRO-THEORY-ATOMIC VAINBERG VM-1986-JETP-LETT+-V44-P9 YAKHONTOV VL-1966-EUR-C-ABSTR-P74
Source item page count:	9
Publication Date:	MAR
IDS No.:	XH056
29-char source abbrev:	J EXP THEOR PHYS

Record 19 of 74
Author(s):	Ivanov IA
Title:	Stark effect in hydrogen: Reconstruction of the complex ground-state energy from the coefficients of an asymptotic perturbation expansion
Source:	PHYSICAL REVIEW A 1997, Vol 56, Iss 1, pp 202-207
No. cited references:	36
Addresses:	Ivanov IA, RUSSIAN ACAD SCI, INST SPECT, TROITSK 142092, MOSCOW REGION, RUSSIA.
KeywordsPlus:	RAYLEIGH-RITZ FORMALISM; ELECTRIC-FIELD; ATOMIC-HYDROGEN; RESONANCES; IONIZATION; EIGENVALUES; SERIES; REAL; PHOTOIONIZATION; APPROXIMANTS
Abstract:	We consider the Stark effect for the ground state of hydrogen. Using the Borel summability of the Rayleigh-Schrodinger perturbation expansion we sum it about the pure imaginary field strength E = iF, F is real. As a result we obtain the series converging for small values of F. We give arguments that this series converges for all positive finite values of F. The series obtained can be continued analytically back to the real field strength region. This method allows one to obtain accurate results for the hydrogenic Stark resonances with slight computational effort.
Cited references:	ALEXANDER MH-1969-PHYS-REV-V178-P34 ALVAREZ G-1994-PHYS-REV-A-V50-P4679 ALVAREZ G-1991-PHYS-REV-A-V44-P3060 BENASSI L-1980-J-PHYS-B-AT-MOL-OPT-V13-P911 BENASSI L-1979-PHYS-REV-LETT-V42-P704 BERGEMAN T-1984-PHYS-REV-LETT-V53-P775 BRANDAS E-1977-PHYS-REV-A-V16-P2207 CALICETI E-1993-COMMUN-MATH-PHYS-V157-P347 CALICETI E-1986-COMMUN-MATH-PHYS-V104-P163 DAMBURG RJ-1976-J-PHYS-B-AT-MOL-OPT-V9-P3149 FERNANDEZ FM-1996-PHYS-REV-A-V54-P1206 FIKHTENGOLTS GM-1992-LEKTCII-DIFFERENTCIA FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 GRADSHTEYN IS-1965-TABLES-INTEGRALS-SER GRAFFI S-1978-COMMUN-MATH-PHYS-V62-P83 HEHENBERM-1974-PHYS-REV-A-V10-P1494 HERBST IW-1978-PHYS-REV-LETT-V41-P67 HIRSCHFELDER JO-1971-J-CHEM-PHYS-V55-P1395 LOEFFEL JJ-1990-LARGE-ORDER-BEH-PERT-P524 MAQUET A-1983-PHYS-REV-A-V27-P2946 POPOV VS-1990-PHYS-LETT-A-V149-P418 PRIVMAN V-1980-PHYS-REV-A-V22-P1833 PRUDNIKOV AP-1981-INTEGRALY-RYADY REINHARDT WP-1982-INT-J-QUANTUM-CHEM-V21-P133 REINHARDT WP-1976-INT-J-QUANTUM-CHEM-S-V10-P359 ROTTKE H-1986-PHYS-REV-A-V33-P301 SIEGERT AFJ-1939-PHYS-REV-V56-P750 SILVERMAN JN-1988-CHEM-PHYS-LETT-V153-P61 SILVERMAN JN-1986-CHEM-PHYS-LETT-V128-P466 SILVERMAN JN-1988-PHYS-REV-A-V37-P1208 SILVERSTONE HJ-1986-INT-J-QUANTUM-CHEM-V29-P261 SILVERSTONE HJ-1979-PHYS-REV-LETT-V43-P1498 SIMON B-1973-ANN-MATH-V97-P247 STEBBINGS RF-1976-SCIENCE-V193-P537 TELNOV DA-1989-J-PHYS-B-AT-MOL-OPT-V22-PL399 TITCHMARSH EC-1958-EIGENFUNCTION-EXPANS
Source item page count:	6
Publication Date:	JUL
IDS No.:	XL645
29-char source abbrev:	PHYS REV A

Record 20 of 74
Author(s):	Goodson DZ
Title:	Self-consistent-field perturbation theory for the Schrodinger equation
Source:	PHYSICAL REVIEW A 1997, Vol 55, Iss 6, pp 4155-4163
No. cited references:	57
Addresses:	Goodson DZ, SO METHODIST UNIV, DEPT CHEM, DALLAS, TX 75275.
KeywordsPlus:	LARGE-DIMENSION LIMIT; COMPLEX ENERGY EIGENVALUES; QUANTUM-MECHANICS; 2-ELECTRON ATOMS; COORDINATE SEPARATION; EXCITED-STATES; SYSTEMS; EXPANSION; HELIUM
Abstract:	A method is developed for using large-order perturbation theory to solve the systems of coupled differential equations that result from the variational solution of the Schrodinger equation with wave functions of product form. This is a noniterative, computationally efficient way to solve self-consistent-field (SCF) equations. Possible applications include electronic structure calculations using products of functions of collective coordinates that include electron correlation, vibrational SCF calculations for coupled anharmonic oscillators with selective coupling of normal modes, and ab initio calculations of molecular vibration spectra without the Born-Oppenheimer approximation.
Cited references:	AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BOWMAN JM-1986-ACCOUNTS-CHEM-RES-V19-P202 CARNEY GD-1988-J-CHEM-SOC-FARAD-T-2-V84-P1277 CHATTERJEE A-1990-PHYS-REP-V186-P249 CHRISTOFFEL KM-1982-CHEM-PHYS-LETT-V85-P220 CIZEK J-1993-J-CHEM-PHYS-V99-P7331 COHEN JM-1996-INT-J-QUANTUM-CHEM-V59-P445 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DUNN M-1996-J-CHEM-PHYS-V104-P9870 DUNN M-1994-J-CHEM-PHYS-V101-P5987 ELOUT MO-UNPUB FARRELLY D-1994-CHEM-PHYS-LETT-V217-P520 FARRELLY D-1986-J-CHEM-PHYS-V84-P6285 FOCK V-1930-Z-PHYSIK-V61-P126 FRANTZ DD-1988-CHEM-PHYS-V126-P59 GERBER RB-1988-ADV-CHEM-PHYS-V70-P97 GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GERMANN TC-1995-THESIS-HARVARD-U GOODSON DZ-1993-DIMENSIONAL-SCALING-P359 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1996-NEW-METHODS-QUANTUM-P71 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 GOODSON DZ-1992-PHYS-REV-A-V46-P5428 GOSCINSKI O-1986-INT-J-QUANTUM-CHEM-V29-P897 HARTREE DR-1928-P-CAMBRIDGE-PHIL-SOC-V24-P89 HARTREE DR-1928-P-CAMBRIDGE-PHIL-SOC-V24-P111 HERSCHBACH DR-1993-DIMENSIONAL-SCALING-P61 HERSCHBACH DR-1996-INT-J-QUANTUM-CHEM-V57-P295 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 HERZBERG G-1945-MOL-SPECTRA-MOL-STRU-P109 LIN CD-1974-PHYS-REV-A-V10-P1986 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1996-NEW-METHODS-QUANTUM-P1 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MACEK J-1968-J-PHYSICS-B-V1-P831 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 MLODINOW LD-1982-PROGR-PARTICLE-NUCL-V8-P387 MUJICA V-1987-CHEM-PHYS-V112-P159 MUR VD-1990-SOV-PHYS-JETP-V70-P16 POPOV VS-1994-PHYS-LETT-A-V193-P165 SERGEEV AV-1989-SOV-J-NUCL-PHYS+-V50-P589 SERGEEV AV-UNPUB SERGEV AV-IN-PRESS-INT-J-QUANT SLATER JC-1930-PHYS-REV-V35-P210 SLATER JC-1929-PHYS-REV-V34-P1293 SLATER JC-1960-QUANTUM-THEORY-ATOMI-V1-P219 SUVERNEV AA-IN-PRESS-CHEM-PHYS-L SUVERNEV AA-1997-J-CHEM-PHYS-V106-P2681 TAN AL-1993-DIMENSIOAL-SCALING-C-P230 TOBIN FL-1980-CHEM-PHYS-V47-P151 TRAYNOR CA-1993-J-PHYS-CHEM-US-V97-P2464 VANDERMERWE PD-1988-PHYS-REV-A-V38-P1187 WATSON DK-1995-PHYS-REV-A-V51-PR5 YAFFE LG-1982-REV-MOD-PHYS-V54-P407
Source item page count:	9
Publication Date:	JUN
IDS No.:	XE372
29-char source abbrev:	PHYS REV A

Record 21 of 74
Author(s):	Popov VS; Karnakov BM; Mur VD
Title:	Quasiclassical theory of atomic ionization in electric and magnetic fields
Source:	PHYSICS LETTERS A 1997, Vol 229, Iss 5, pp 306-312
No. cited references:	44
Addresses:	Popov VS, INST THEORET & EXPT PHYS, RU-117259 MOSCOW, RUSSIA. MOSCOW STATE PHYS ENGN INST, RU-115409 MOSCOW, RUSSIA.
Author Keywords:	ionization of atoms; quasiclassics; imaginary time method
KeywordsPlus:	ORDER PERTURBATION-THEORY; HYDROGEN-ATOM; MULTIDIMENSIONAL PROBLEMS; RYDBERG ATOMS; 1/N-EXPANSION; THRESHOLD
Abstract:	Using the ''imaginary time'' method we have calculated (in the quasiclassical approximation) the probability of ionization of the atomic s-state in static electric and magnetic fields. The Coulomb interaction between the emitted electron and the atomic remainder is taken into account. The results obtained are valid for external fields E and H which are smaller than characteristic atomic fields. The case of mutually orthogonal fields (the Lorentz ionization) is carefully studied. (C) 1997 Elsevier Science B.V.
Cited references:	ANDREEV SP-1985-PISMA-ESKP-TEOR-FIZ-V42-P154 ANDREYEV SP-1984-ZH-EKSP-TEOR-FIZ+-V86-P866 BEKENSTEIN JD-1969-PHYS-REV-V188-P130 CHU MC-1984-PHYS-REV-A-V29-P675 CHU MC-1983-PHYS-REV-A-V28-P1423 DAMBURG RJ-1978-J-PHYS-B-AT-MOL-OPT-V11-P1921 DAMBURG RJ-1976-J-PHYS-B-AT-MOL-OPT-V9-P3149 DEMKOV YN-1964-ZH-EKSP-TEOR-FIZ-V47-P918 DRUKAREV GF-1971-ZH-EKSP-TEOR-FIZ-V61-P956 FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 GORKOV LP-1967-ZH-EKSP-TEO-V53-P717 JOHNSON BR-1983-PHYS-REV-LETT-V51-P2280 KELDYSH LV-1964-ZH-EKSP-TEOR-FIZ-V47-P1945 KOLOSOV VV-1989-J-PHYS-B-AT-MOL-OPT-V22-P833 KOTOVA LP-1968-ZH-EKSP-TEOR-FIZ-V54-P1151 LANDAU LD-1977-QUANTUM-MECHANICS LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MAGARILL LI-1971-ZH-EKSP-TEOR-FIZ-V60-P175 MAIN J-1994-J-PHYS-B-AT-MOL-OPT-V27-P2835 MANAKOV NL-1986-ZH-EKSP-TEOR-FIZ+-V91-P404 MELEZHIK VS-1993-PHYS-REV-A-V48-P4528 NIKISHOV AI-1967-ZH-EKSP-TEO-V52-P223 NIKISHOV AI-1966-ZH-EKSP-TEOR-FIZ-V50-P255 PERELOMOV AM-1966-ZH-EKSP-TEO-V51-P309 PERELOMOV AM-1966-ZH-EKSP-TEOR-FIZ+-V50-P1393 PERELOMOV AM-1967-ZHETF-V52-P514 POPOV VS-1994-PHYS-LETT-A-V193-P165 POPOV VS-1993-PHYS-LETT-A-V172-P193 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 POPOV VS-1967-ZH-EKSP-TEO-V53-P331 POPOV VS-1994-ZH-EKSP-TEOR-FIZ+-V105-P568 POPOV VS-1992-ZH-EKSP-TEOR-FIZ+-V102-P1453 SEIPP I-1996-J-PHYS-B-AT-MOL-OPT-V29-P1 SMIRNOV BM-1965-ZHETF-V49-P841 SOLOVEV EA-1983-ZH-EKSP-TEOR-FIZ+-V85-P109 TURBINER AV-1989-ZH-EKSP-TEOR-FIZ+-V95-P1152 TURBINER AV-1983-ZH-EKSP-TEOR-FIZ+-V84-P1329 WEINBERG VM-1987-JETP-LETT+-V46-P178 WEINBERG VM-1986-PISMA-ZH-EKSP-TEOR-F-V44-P9 WEINBERG VM-1990-ZH-EKSP-TEOR-FIZ-V98-P847 WEINBERG VM-1987-ZH-EKSP-TEOR-FIZ+-V93-P450 YAMABE T-1977-PHYS-REV-A-V16-P877
Source item page count:	7
Publication Date:	MAY 26
IDS No.:	XA531
29-char source abbrev:	PHYS LETT A

Record 22 of 74
Author(s):	Karnakov BM; Mur VD; Popov VS
Title:	Contribution to the theory of Lorentzian ionization
Source:	JETP LETTERS 1997, Vol 65, Iss 5, pp 405-411
No. cited references:	13
Addresses:	Karnakov BM, TECH UNIV, MOSCOW ENGN PHYS INST, MOSCOW 115409, RUSSIA. INST THEORET & EXPT PHYS, MOSCOW 117259, RUSSIA.
Abstract:	The probability w(L) of Lorentzian ionization, which arises when an atom or ion moves in a constant magnetic held, is calculated in the quasiclassical approximation. The nonrelativistic (upsilon less than or similar to e(2)/(h) over bar = 1, upsilon is the velocity of the atom) and ultrarelativistic (upsilon --> c = 137) cases are examined and the stabilization factor S, which takes account of the effect of the magnetic field on tunneling of an electron, is found. (C) 1997 American Institute of Physics.
Cited references:	BITTER D-1965-SCI-AM-V213-P65 DELONE NB-1985-ATOMS-STRONG-LIGHT-F GREINER W-1985-QUANTUM-ELECTRODYNAM KELDYSH LV-1965-ZH-EKSP-TEOR-FIZ+-V20-P1307 KOTOVA LP-1968-SOV-PHYS-JETP-V27-P616 PAVLOVSKII AI-1995-SCI-WORKS-P85 PERELOMOV AM-1967-ZH-EKSP-TEOR-FIZ+-V24-P207 PERELOMOV AM-1966-ZH-EKSP-TEOR-FIZ+-V23-P924 POPOV VS-1996-JETP-LETT+-V63-P417 SAKHAROV AD-1995-SCI-WORKS SAKHAROV AD-1966-SOV-PHYS-DOKL-V10-P1045 SCHWINGER J-1951-PHYS-REV-V82-P664 ZELDOVICH YB-1972-SOV-PHYS-USP-V14-P673
Source item page count:	7
Publication Date:	MAR 10
IDS No.:	WT775
29-char source abbrev:	JETP LETT-ENGL TR

Record 23 of 74
Author(s):	Rao JG; Li BW
Title:	Theoretical calculations of Rydberg stark effect of hydrogen atom
Source:	COMMUNICATIONS IN THEORETICAL PHYSICS 1997, Vol 27, Iss 1, pp 9-14
No. cited references:	13
Addresses:	Rao JG, CHINESE ACAD SCI, LAB MAGNET RESONANCE & ATOM & MOL PHYS, WUHAN 430071, PEOPLES R CHINA. CHINESE ACAD SCI, WUHAN INST PHYS, WUHAN 430071, PEOPLES R CHINA. CCAST, WORLD LAB, BEIJING 100080, PEOPLES R CHINA.
KeywordsPlus:	B-SPLINE APPROACH; MAGNETIC-FIELD; PHOTOIONIZATION; SPECTRUM; STATES
Abstract:	The Stark shifts and widths of the highly excited states near the classical ionization threshold of a hydrogen atom are calculated by the B spline technique plus complex scaling method. The Lanczos method has been used in our calculations and is proved to be powerful. Our results are in agreement with the experimental results and theoretical ones obtained by other methods. The method can also be used to calculate the same problem for atoms in parallel and cross electric and magnetic fields.
Cited references:	DEBOOR C-1978-PRACTICAL-GUIDE-SPLI DELANDE D-1991-PHYS-REV-LETT-V66-P141 ERICSSON T-1980-MATH-COMPUT-V35-P1251 FISHER CF-1990-J-COMPUT-PHYS-V90-P489 GLAB WL-1985-PHYS-REV-A-V31-P3677 HARMIN DA-1982-PHYS-REV-LETT-V49-P128 JOHNSON WR-1988-PHYS-REV-A-V37-P307 LIU WY-1993-PHYS-REV-A-V47-P3151 NG K-1987-PHYS-REV-A-V35-P2508 POPOV VS-1990-PHYS-LETT-A-V149-P418 RAO JG-1994-PHYS-REV-A-V50-P1916 REHARDT WP-1982-ANNU-REV-PHYS-CHEM-V33-P223 XI JH-1992-PHYS-REV-A-V46-P3151
Source item page count:	6
Publication Date:	JAN 30
IDS No.:	WP252
29-char source abbrev:	COMMUN THEOR PHYS

Record 24 of 74
Author(s):	Suvernev AA; Goodson DZ
Title:	Perturbation theory for coupled anharmonic oscillators
Source:	JOURNAL OF CHEMICAL PHYSICS 1997, Vol 106, Iss 7, pp 2681-2684
No. cited references:	24
Addresses:	Suvernev AA, SO METHODIST UNIV, DEPT CHEM, DALLAS, TX 75275.
KeywordsPlus:	BOUND-STATES; EIGENVALUES; MOLECULES; QUANTIZATION; VIBRATIONS; EXPANSION; EQUATION; DYNAMICS
Abstract:	Perturbation theory is applied to a pair of coupled oscillators with cubic anharmonicity. Large-order perturbation theory is shown to be more efficient computationally than numerical diagonalization of the Hamiltonian. Quadratic Pade summation of the energy expansions yields convergent results for the real and the imaginary parts of resonance eigenvalues. (C) 1997 American Institute of Physics.
Cited references:	ACTON FS-1970-NUMERICAL-METHODS-WO-P332 BACIC Z-1989-ANNU-REV-PHYS-CHEM-V40-P469 BAKER GA-1996-PADE-APPROXIMANTS-1 BOWMAN JM-1991-J-CHEM-PHYS-V94-P454 CHANG J-1986-J-CHEM-PHYS-V84-P4997 DAVIS MJ-1981-J-CHEM-PHYS-V75-P246 DUNN M-IN-PRESS-J-CHEM-PHYS DUNN M-1994-J-CHEM-PHYS-V101-P5987 EASTES W-1974-J-CHEM-PHYS-V61-P4301 FORD J-1973-ADV-CHEM-PHYS-V24-P155 FRIED LE-1989-J-CHEM-PHYS-V90-P6378 FRIED LE-1987-J-CHEM-PHYS-V86-P6270 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GOODSON DZ-1988-CHEM-PHYS-LETT-V151-P557 HIRSCHFELDER JO-1964-ADVAN-QUANTUM-CHEM-V1-P255 JAFFE C-1982-J-CHEM-PHYS-V77-P5191 KAIS S-1993-J-CHEM-PHYS-V98-P3990 LAWTON RT-1979-MOL-PHYS-V37-P1799 PARLETT BN-1980-SYMMETRIC-EIGENVALUE-P119 SHAFER RE-1972-SIAM-J-NUMER-ANAL-V11-P447 SIBERT EL-1988-J-CHEM-PHYS-V88-P4378 STEFANSKI K-1987-J-CHEM-PHYS-V87-P1079 VAINBERG VM-1986-JETP-LETT+-V44-P9 VAINBERG VM-1988-THEOR-MATH-PHYS+-V74-P269
Source item page count:	4
Publication Date:	FEB 15
IDS No.:	WH024
29-char source abbrev:	J CHEM PHYS

Record 25 of 74
Author(s):	Germann TC; Kais S
Title:	Dimensional perturbation theory for Regge poles
Source:	JOURNAL OF CHEMICAL PHYSICS 1997, Vol 106, Iss 2, pp 599-604
No. cited references:	26
Addresses:	Germann TC, UNIV CALIF BERKELEY, DEPT CHEM, BERKELEY, CA 94720. PURDUE UNIV, DEPT CHEM, W LAFAYETTE, IN 47907.
KeywordsPlus:	CIRCULAR RYDBERG STATES; SEMICLASSICAL CALCULATION; VARIABLE DIMENSIONALITY; 2-ELECTRON ATOMS; MAGNETIC-FIELD; QUANTUM; POSITIONS; RESIDUES; TRAJECTORIES; POTENTIALS
Abstract:	We apply dimensional perturbation theory to the calculation of Regge pole positions, providing a systematic improvement to earlier analytic first-order results. We consider the orbital angular momentum l as a function of spatial dimension D for a given energy E, and expand l in inverse powers of kappa=(D-1)/2. It is demonstrated for both bound and resonance states that the resulting perturbation series often converges quite rapidly, so that accurate quantum results can be obtained via simple analytic expressions given here through third order. For the quartic oscillator potential, the rapid convergence of the present l(D;E) series is in marked contrast with the divergence of the more traditional E(D;l) dimensional perturbation series, thus offering an attractive alternative for bound state problems. (C) 1997 American Institute of Physics.
Cited references:	BOSANAC S-1978-J-MATH-PHYS-V19-P789 CONNOR JNL-COMMUNICATION CONNOR JNL-1990-J-CHEM-SOC-FARADAY-T-V86-P1627 CONNOR JNL-1979-J-PHYS-B-AT-MOL-OPT-V12-PL515 CONNOR JNL-1976-J-PHYS-B-AT-MOL-OPT-V9-P1783 DELOS JB-1975-PHYS-REV-A-V11-P210 DUNN M-1994-J-CHEM-PHYS-V101-P5987 GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GERMANN TC-1995-J-PHYS-B-AT-MOL-OPT-V28-PL531 GERMANN TC-1995-PHYS-REV-LETT-V74-P658 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-PHYS-REV-A-V11-P42 KAIS S-1993-J-CHEM-PHYS-V98-P3990 KAIS S-1993-J-PHYS-CHEM-US-V97-P2453 KOBYLINSKY NA-1990-PHYS-LETT-B-V235-P182 PAJUNEN P-1988-J-CHEM-PHYS-V88-P4268 POPOV VS-1987-PHYS-LETT-A-V124-P77 SOKOLOVSKI D-1995-J-CHEM-PHYS-V103-P5979 SUKUMAR CV-1975-J-PHYS-B-AT-MOL-OPT-V8-P568 TAYLOR JR-1972-SCATTERING-THEORY-P302 THYLWE KE-1989-LECTURE-NOTES-PHYSIC-V325-P281 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470 VAINBERG VM-1988-THEOR-MATH-PHYS+-V74-P269
Source item page count:	6
Publication Date:	JAN 8
IDS No.:	WB843
29-char source abbrev:	J CHEM PHYS

Record 26 of 74
Author(s):	Dunn M; Watson DK
Title:	Continuation of the Schrodinger equation for higher angular-momentum states to D dimensions and interdimensional degeneracies
Source:	FEW-BODY SYSTEMS 1996, Vol 21, Iss 3-4, pp 187-209
No. cited references:	151
Addresses:	Dunn M, UNIV OKLAHOMA, DEPT PHYS & ASTRON, NORMAN, OK 73019.
KeywordsPlus:	DOUBLY-EXCITED-STATES; MOLECULAR-ORBITAL DESCRIPTION; SHIFTED 1/N EXPANSION; HELIUM ISOELECTRONIC SEQUENCE; ROTATING MORSE OSCILLATOR; BARRIER STARK RESONANCES; QUASI-STATIONARY STATES; UNIFORM MAGNETIC-FIELD; WEAKLY-BOUND SYSTEMS; LARGE-N EXPANSIONS
Abstract:	The application of the techniques of dimensional scaling, and in particular the 1/D expansion, to higher angular-momentum states of multielectron atoms requires the generalized Euler angles, which multiply with increasing D to be ''factored out'' of the wave function. The factorization must be performed in a way that produces from the Schrodinger equation a tractable set of differential equations which admit continuation in the dimension D. In two recent works the authors have achieved the necessary factorization of the wave function by generalizing the Schwartz expansion to N electrons in D dimensions. The present paper applies the N-electron D-dimensional Schwartz expansion to the two-electron problem in D dimensions. The resulting set of coupled differential equations in the internal variables admit continuation in D, enabling the methods of dimensional scaling to be applied to higher-angular-momentum states. In addition, the coupled differential equations clearly show the complete spectrum of exact interdimensional degeneracies of the two-electron system.
Cited references:	ADER JP-1983-PHYS-LETT-A-V97-P178 ARTECA GA-1990-LARGE-ORDER-PERTURBA ATAG S-1988-PHYS-REV-A-V37-P2280 AVERY J-1992-INT-J-QUANTUM-CHEM-V41-P673 AVERY J-1991-INT-J-QUANTUM-CHEM-V39-P657 AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BAG M-1990-J-PHYS-B-AT-MOL-OPT-V23-P3075 BAG M-1992-PHYS-REV-A-V46-P6059 BAKER JD-1990-PHYS-REV-A-V41-P1247 BENDER CM-1982-PHYS-REV-A-V25-P1305 BERLIN TH-1952-PHYS-REV-V86-P821 BERRY RS-1988-ADV-CHEM-PHYS-V70-P35 BERRY RS-1989-CONTEMP-PHYS-V30-P1 BOERNER H-1963-REPRESENTATIONS-GROU BOLLE D-1984-PHYS-REV-A-V30-P1279 BOTTCHER C-1994-PHYS-REV-A-V49-P1714 BOYA LJ-1994-PHYS-REV-A-V50-P4397 CARZOLI JC-UNPUB CASATI G-1996-QUANTUM-CHAOS-V119-P113 CHATTERJEE A-1990-PHYS-REP-V186-P249 CHISHOLM CDH-1976-GROUP-THEORETICAL-TE-PCH8 DIRAC PAM-1930-PRINCIPLES-QUANTUM-M DOREN DJ-1985-CHEM-PHYS-LETT-V118-P115 DOREN DJ-1987-J-CHEM-PHYS-V87-P433 DOREN DJ-1986-J-CHEM-PHYS-V85-P4557 DOREN DJ-1988-J-PHYS-CHEM-US-V92-P1816 DUNN M-IN-PRESS-ANN-PHYS-NY DUNN M-1994-J-CHEM-PHYS-V101-P5987 DUNN M-1990-J-PHYS-B-AT-MOL-OPT-V23-P2435 DUNN M-1993-J-PHYS-CHEM-US-V97-P2457 DUNN M-UNPUB-LARGE-DIMENSIO DUNN M-UNPUB-ORIGIN-EXACT-I EZRA GS-1991-J-PHYS-B-AT-MOL-OPT-V24-PL413 FEAGIN JM-1988-PHYS-REV-A-V37-P4599 FEAGIN JM-1986-PHYS-REV-LETT-V57-P984 FRANTZ DD-1988-CHEM-PHYS-V126-P59 FRANTZ DD-1990-J-CHEM-PHYS-V92-P6668 FRANTZ DD-1989-PHYS-REV-A-V40-P1175 GANGYOPADHYAY RS-1985-PHYS-REV-D-V32-P3312 GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GERMANN TC-1995-PHYS-REV-LETT-V74-P658 GONZALEZ A-1991-FEW-BODY-SYST-V10-P43 GOODSON DZ-1993-DIMENSIONAL-SCALING-P275 GOODSON DZ-1993-DIMENSIONAL-SCALING-P359 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 GOODSON DZ-1992-PHYS-REV-A-V46-P5428 GOODSON DZ-1991-PHYS-REV-A-V44-P97 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 GOSCINSKI O-1986-INT-J-QUANTUM-CHEM-V29-P897 GRUJIC PV-1995-J-PHYS-B-AT-MOL-OPT-V28-P1159 HAMERMESH M-1989-GROUP-THEORY-ITS-APP-PCH10 HERRICK DR-1983-ADV-CHEM-PHYS-V52-P1 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-J-MATH-PHYS-V16-P1047 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1989-AT-PHYS-V11-P63 HERSCHBACH DR-1993-DIMENSIONAL-SCALING HERSCHBACH DR-1993-DIMENSIONAL-SCALING-P25 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1989-P-WELSCH-FD-CHEM-RES-V32-P95 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 HERSHBACH DR-1987-FARADAY-DISC-CHEM-SO-V84-P465 INTHOOFT G-1980-NATO-ADV-STUDY-I-B-V59 KAIS S-1992-CHEM-PHYS-V161-P393 KAIS S-1994-INT-J-QUANTUM-CHEM-V49-P657 KAIS S-1994-J-CHEM-PHYS-V100-P4367 KAIS S-1993-J-CHEM-PHYS-V99-P417 KAIS S-1993-J-CHEM-PHYS-V99-P5184 KAIS S-1993-J-CHEM-PHYS-V98-P3990 KAIS S-1991-J-CHEM-PHYS-V95-P9028 KAIS S-1989-J-CHEM-PHYS-V91-P7791 KAIS S-1994-J-PHYS-CHEM-US-V98-P11015 KAIS S-1993-J-PHYS-CHEM-US-V97-P2453 KELLMAN ME-1994-PHYS-REV-LETT-V73-P2543 KELLMAN ME-1985-PHYS-REV-LETT-V55-P1738 KVENTSEL GF-1981-PHYS-REV-A-V24-P2299 LIN CD-1986-ADV-ATOM-MOL-PHYS-V22-P77 LIN CD-1995-PHYS-REP-V257-P1 LIN CD-1984-PHYS-REV-A-V29-P1019 LIN CD-1993-REV-FUNDAMENTAL-PROC-P357 LOESER JG-1994-J-CHEM-PHYS-V100-P5036 LOESER JG-1991-J-CHEM-PHYS-V95-P4525 LOESER JG-1987-J-CHEM-PHYS-V86-P2114 LOESER JG-1987-J-CHEM-PHYS-V86-P3512 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1986-J-CHEM-PHYS-V84-P3882 LOESER JG-1986-J-CHEM-PHYS-V84-P3893 LOESER JG-1985-J-PHYS-CHEM-US-V89-P3444 LOPEZCABRERA M-1993-J-PHYS-CHEM-US-V97-P2467 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MALUENDES SA-1986-PHYS-REV-D-V34-P1835 MARCH NH-1985-J-MATH-PHYS-V26-P554 MARCH NH-1986-PHYS-REV-A-V34-P5106 MARCH NH-1984-PHYS-REV-A-V30-P2936 MLODINOW LD-1981-ANN-PHYS-NEW-YORK-V131-P1 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MORALES DA-1989-CHEM-PHYS-LETT-V161-P253 MULLER J-1992-PHYS-REV-A-V45-P1471 MUR VD-1990-SOV-PHYS-JETP-V70-P16 MUSTAFA O-1993-J-PHYS-CONDENS-MATT-V5-P1333 MUSTAFA O-1994-PHYS-REV-A-V50-P2926 POPOV VS-1994-JETP-LETT+-V59-P158 POPOV VS-1994-PHYS-LETT-A-V193-P159 POPOV VS-1994-PHYS-LETT-A-V193-P165 POPOV VS-1993-PHYS-LETT-A-V173-P63 POPOV VS-1993-PHYS-LETT-A-V172-P193 POPOV VS-1991-PHYS-LETT-A-V157-P185 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 POPOV VS-1992-SOV-J-NUCL-PHYS-V54-P968 ROST JM-1991-J-PHYS-B-AT-MOL-OPT-V24-P2455 ROST JM-1991-J-PHYS-B-AT-MOL-OPT-V24-P4293 ROST JM-1993-J-PHYS-CHEM-US-V97-P2461 ROST JM-1992-PHYS-REV-A-V46-P2410 RUDNICK J-1987-SCIENCE-V237-P384 SCHULTZ DR-1994-PHYS-REV-A-V50-P1348 SCHWARTZ C-1961-PHYSICAL-REVIEW-V123-P1700 STANLEY HE-1968-PHYS-REV-V176-P718 STEPANOV SS-1991-SOV-PHYS-JETP-V73-P227 SUKHATME UP-1986-PHYS-REV-D-V33-P1166 SUNG SM-1993-J-PHYS-CHEM-US-V97-P2479 TRAYNOR CA-1993-J-PHYS-CHEM-US-V97-P2464 VAINBERG VM-1987-JETP-LETT+-V46-P225 VAINBERG VM-1986-JETP-LETT+-V44-P9 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470 VAINBERG VM-1988-THEOR-MATH-PHYS+-V74-P269 VAINBERG VM-1987-ZH-EKSP-TEOR-FIZ+-V66-P258 VALONE SM-1994-INT-J-QUANTUM-CHEM-V49-P591 VANDERMERWE PD-1985-J-CHEM-PHYS-V82-P5293 VANDERMERWE PD-1984-J-CHEM-PHYS-V81-P5976 VANDERMERWE PD-1989-PHYS-REV-A-V40-P1785 VANDERMERWE PD-1986-PHYS-REV-A-V34-P3452 VANDERMERWE PDT-1987-PHYS-REV-A-V36-P3446 VARSHNI YP-1993-CAN-J-PHYS-V71-P122 VARSHNI YP-1994-CHEM-PHYS-V188-P197 WATSON DK-1995-PHYS-REV-A-V51-PR5 WEYL H-1939-CLASSICAL-GROUPS WILSON KG-1983-REV-MOD-PHYS-V55-P583 WINTGEN D-1992-CHAOS-V2-P19 WINTGEN D-1994-PROG-THEOR-PHYS-SUPP-V116-P121 WITTEN E-1980-PHYS-TODAY-V33-P38 YAFFE LG-1983-PHYS-TODAY-V36-P50 YAFFE LG-1982-REV-MOD-PHYS-V54-P407 ZHEN Z-1993-DIMENSIONAL-SCALING-P83 ZHEN Z-1993-DIMENSIONAL-SCALING-P429 ZHENG Z-1993-DIMENSIONAL-SCALING-P230
Source item page count:	23
IDS No.:	WC743
29-char source abbrev:	FEW-BODY SYST

Record 27 of 74
Author(s):	Dunn M; Watson DK
Title:	Continuation of the wave function for higher angular momentum states to D dimensions .1. The generalized Schwartz expansion
Source:	ANNALS OF PHYSICS 1996, Vol 251, Iss 2, pp 266-318
No. cited references:	311
Addresses:	Dunn M, UNIV OKLAHOMA, DEPT PHYS & ASTRON, NORMAN, OK 73019.
KeywordsPlus:	SHIFTED 1/N EXPANSION; LARGE-N-EXPANSION; DOUBLY-EXCITED-STATES; MOLECULAR-ORBITAL DESCRIPTION; KLEIN-GORDON EQUATION; INVERSE SCATTERING TRANSFORMATION; HELIUM ISOELECTRONIC SEQUENCE; ROTATING MORSE OSCILLATOR; BARRIER STARK RESONANCES; QUASI-STATIONARY STATES
Abstract:	Extending the techniques of dimensional scaling to higher angular momentum states of multi-electron atoms requires the derivation, from the Schrodinger equation, of a tractable set of differential equations which admit continuation in the spatial dimension D. This derivation centers on ''factoring out,'' in D dimensions, the rotational degrees of freedom from the internal degrees of freedom in the wave function. A solution to this problem, by generalizing thr Schwartz expansion (Schwartz, Phys. Rev. 123, 1700 (1961)) to N electrons in D dimensions, is presented. The generalization to systems with particles of arbitrary masses is straightforward. (C) 1996 Academic Press, Inc.
Cited references:	ADER JP-1983-PHYS-LETT-A-V97-P178 ALVES NA-1988-J-PHYS-A-MATH-GEN-V21-P3215 ANDREW K-1990-AM-J-PHYS-V58-P1177 ARFKEN G-1985-MATH-METHODS-PHYSICI-P179 ARTECA GA-1990-LARGE-ORDER-PERTURBA ATAG S-1989-J-MATH-PHYS-V30-P696 ATAG S-1988-PHYS-REV-A-V37-P2280 AU CK-1991-J-PHYS-B-AT-MOL-OPT-V24-P4671 AVAN J-1984-NUCL-PHYS-B-V237-P159 AVAN J-1983-NUCL-PHYS-B-V224-P61 AVAN J-1984-PHYS-REV-D-V29-P2891 AVAN J-1984-PHYS-REV-D-V29-P2904 AVERY J-1993-DIMENSIONAL-SCALING-P139 AVERY J-1992-INT-J-QUANTUM-CHEM-V41-P673 AVERY J-1991-INT-J-QUANTUM-CHEM-V39-P657 AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BAG M-1990-J-PHYS-B-AT-MOL-OPT-V23-P3075 BAG M-1992-PHYS-REV-A-V46-P6059 BARUT AO-1977-THEORY-GROUP-REPRESE-P291 BELOV AA-1989-PHYS-LETT-A-V142-P389 BELOV AA-1990-SOV-PHYS-JETP-V71-P12 BELOV AA-1988-SOV-PHYS-JETP-V67-P2413 BELOV AA-1989-THEOR-MATH-PHYS+-V81-P1294 BENDER CM-1978-ADV-MATH-METHODS-SCI BENDER CM-1994-J-MATH-PHYS-V35-P368 BENDER CM-1982-PHYS-REV-A-V25-P1305 BENDER CM-1995-PHYS-REV-D-V51-P1875 BENDER CM-1994-PHYS-REV-D-V50-P6547 BENDER CM-1993-PHYS-REV-D-V48-P4919 BENDER CM-1992-PHYS-REV-D-V46-P5557 BENDER CM-1992-PHYS-REV-LETT-V68-P3674 BERA PK-1993-PHYS-REV-A-V48-P4764 BERLIN TH-1952-PHYS-REV-V86-P821 BERRY RS-1988-ADV-CHEM-PHYS-V70-P35 BERRY RS-1989-CONTEMP-PHYS-V30-P1 BLINDER SM-1984-J-MATH-PHYS-V25-P905 BOERNER H-1963-REPRESENTATIONS-GROU BOETTCHER S-1995-PHYS-REV-E-V51-P3862 BOETTCHER S-1995-PHYS-REV-LETT-V74-P2410 BOLLE D-1984-PHYS-REV-A-V30-P1279 BOTTCHER C-1994-PHYS-REV-A-V49-P1714 BOYA LJ-1994-PHYS-REV-A-V50-P4397 BRAY AJ-1974-J-PHYS-A-MATH-GEN-V7-P2144 CASATI G-1993-P-INT-SCH-PHYS-ENR-F-P113 CHATTERJEE A-1986-J-MATH-PHYS-V27-P2331 CHATTERJEE A-1986-J-PHYS-A-MATH-GEN-V19-P3707 CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P735 CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P1193 CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P2403 CHATTERJEE A-1990-PHYS-REP-V186-P249 CHATTERJEE A-1987-PHYS-REV-A-V35-P2722 CHATTERJEE A-1986-PHYS-REV-A-V34-P2470 CHISHOLM CDH-1976-GROUP-THEORETICAL-TE-PCH8 CHRISTIANSEN H-1989-PHYS-REV-A-V40-P1760 COURANT R-1953-METHODS-MATH-PHYSICS-V1-P65 CVITANOVIC P-1984-GROUP-THEORY-1 DAHL JP-1993-DIMENSIONAL-SCALING-P165 DEVEGA HJ-1979-COMMUN-MATH-PHYS-V70-P29 DOLGOV AD-1979-PHYS-LETT-B-V86-P185 DOMKE M-1995-PHYS-REV-A-V51-PR4309 DOMKE M-1992-PHYS-REV-LETT-V69-P1171 DOMKE M-1991-PHYS-REV-LETT-V66-P1306 DOREN DJ-1985-CHEM-PHYS-LETT-V118-P115 DOREN DJ-1987-J-CHEM-PHYS-V87-P433 DOREN DJ-1986-J-CHEM-PHYS-V85-P4557 DOREN DJ-1988-J-PHYS-CHEM-US-V92-P1816 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DOREN DJ-1986-PHYS-REV-A-V34-P2665 DUNN M-1996-ANN-PHYS-NEW-YORK-V251-P319 DUNN M-IN-PRESS-FEW-BODY-SY DUNN M-1994-J-CHEM-PHYS-V101-P5987 DUNN M-1990-J-PHYS-B-AT-MOL-OPT-V23-P2435 DUNN M-1993-J-PHYS-CHEM-US-V97-P2457 DUNN M-LARGE-DIMENSION-LIMI DUNN M-UNPUB DUTT R-1987-J-PHYS-B-AT-MOL-OPT-V20-P2437 DUTT R-1986-J-PHYS-B-AT-MOL-OPT-V19-P3411 DUTT R-1985-J-PHYS-B-AT-MOL-OPT-V18-P3311 DUTT R-1986-PHYS-REV-A-V34-P777 DUTT R-1986-Z-PHYS-D-ATOM-MOL-CL-V2-P207 ERKOC S-1986-PHYS-REV-D-V33-P588 EZRA GS-1991-J-PHYS-B-AT-MOL-OPT-V24-PL413 FANO U-1959-IRREDUCIBLE-TESORIAL FEAGIN JM-1988-PHYS-REV-A-V37-P4599 FEAGIN JM-1986-PHYS-REV-LETT-V57-P984 FERRELL RA-1974-PHYS-REV-A-V9-P846 FRANTZ DD-1988-CHEM-PHYS-V126-P59 FRANTZ DD-1990-J-CHEM-PHYS-V92-P6668 FRANTZ DD-1989-PHYS-REV-A-V40-P1175 GALLUP GA-1959-J-MOL-SPECTROSC-V3-P673 GANGOPADHYAY RS-1984-PHYS-REV-A-V30-P594 GANGYOPADHYAY RS-1985-PHYS-REV-D-V32-P3312 GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GERMANN TC-1995-PHYS-REV-LETT-V74-P658 GERRY CC-1983-PHYS-REV-D-V28-P1939 GOLDSCHMIDT YY-1993-NUCL-PHYS-B-V393-P507 GONZALEZ A-1992-FEW-BODY-SYST-V13-P105 GONZALEZ A-1991-FEW-BODY-SYST-V10-P43 GONZALEZ A-1990-FEW-BODY-SYST-V8-P73 GONZALEZ A-1993-J-PHYS-B-AT-MOL-OPT-V26-P1253 GONZALEZ A-1994-REV-MEX-FIS-V40-P12 GONZALEZ A-1993-REV-MEX-FIS-V39-P893 GONZALEZ A-1990-SOV-PHYS-LEBDEV-I-RE-V3-P36 GONZALEZ A-1988-SOV-PHYS-LEBEDEV-I-R-V7-P65 GOODSON DZ-1993-DIMENSIONAL-SCALING-P275 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 GOODSON DZ-1992-PHYS-REV-A-V46-P5428 GOODSON DZ-1991-PHYS-REV-A-V44-P97 GOODSON DZ-1991-PHYS-REV-A-V43-P4617 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 GOSCINSKI O-1986-INT-J-QUANTUM-CHEM-V29-P897 GRUJIC PV-1995-J-PHYS-B-AT-MOL-OPT-V28-P1159 HAGG L-1993-DIMENSIONAL-SCALING-P315 HAMERMESH M-1989-GROUP-THEORY-ITS-APP-PCH10 HARRIS PG-1990-PHYS-REV-A-V42-P6443 HARRIS PG-1990-PHYS-REV-LETT-V65-P309 HERRICK DR-1983-ADV-CHEM-PHYS-V52-P1 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-J-MATH-PHYS-V16-P1047 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERRING C-1962-REV-MOD-PHYS-V34-P631 HERSCHBACH DR-1989-AT-PHYS-V11-P63 HERSCHBACH DR-1993-DIMENSIONAL-SCALING HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1989-P-WELSCH-FD-CHEM-RES-V32-P95 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 HERSHBACH DR-1987-FARADAY-DISC-CHEM-SO-V84-P465 HIKAMI S-1979-J-PHYS-A-MATH-GEN-V12-P759 HOLAS A-1990-CORRELATIONS-ELECTRO-P27 HOLAS A-1991-J-PHYS-A-MATH-GEN-V24-P4249 HOLAS A-1989-PHYS-REV-B-V40-P159 HOLSTEIN T-1952-J-CHEM-PHYS-V56-P832 IKHDAIR S-1992-DOGA-TR-J-PHYS-V16-P510 IKHDAIR SM-1993-Z-PHYS-D-ATOM-MOL-CL-V28-P1 IMBO T-1984-PHYS-LETT-A-V105-P183 IMBO T-1984-PHYS-REV-D-V29-P1669 IMBO TD-1987-PHYS-REV-D-V36-P3438 IMBO TD-1985-PHYS-REV-LETT-V54-P2184 IWAMOTO N-1984-PHYS-REV-A-V30-P2597 IWAMOTO N-1984-PHYS-REV-A-V30-P3289 JAMEEL M-1986-J-PHYS-A-MATH-GEN-V19-P1967 JEVICKI A-1981-ANN-PHYS-NEW-YORK-V136-P113 JEVICKI A-1980-NUCL-PHYS-B-V171-P362 KAIS S-1992-CHEM-PHYS-V161-P393 KAIS S-1994-INT-J-QUANTUM-CHEM-V49-P657 KAIS S-1994-J-CHEM-PHYS-V100-P4367 KAIS S-1993-J-CHEM-PHYS-V99-P417 KAIS S-1993-J-CHEM-PHYS-V99-P5184 KAIS S-1993-J-CHEM-PHYS-V98-P3990 KAIS S-1991-J-CHEM-PHYS-V95-P9028 KAIS S-1989-J-CHEM-PHYS-V91-P7791 KAIS S-1997-J-PHYS-CHEM-US-V97-P2453 KAIS S-1994-J-PHYS-CHEM-US-V98-P11015 KAUSHAL RS-1984-LETT-NUOVO-CIMENTO-V41-P434 KELLMAN ME-1994-PHYS-REV-LETT-V73-P2543 KELLMAN ME-1985-PHYS-REV-LETT-V55-P1738 KING RC-1972-CAN-J-MATH-V33-P176 KOSTELECKY VA-1985-PHYS-REV-D-V32-P2627 KUDINOV AV-1982-CZECH-J-PHYS-B-V32-P556 KUDINOV AV-1983-THEOR-MATH-PHYS+-V56-P871 KVENTSEL GF-1981-PHYS-REV-A-V24-P2299 LAI CH-1987-J-MATH-PHYS-V28-P1801 LANDAU LD-1965-QUANTUM-MECHANICS-P312 LANGMUIR I-1919-J-AM-CHEMICAL-SOC-V41-P868 LAWDEN DF-1962-INTRO-TENSOR-CALCULU LEGUILLOU JC-1990-LARGE-ORDER-BEHAV-PE LEWIS GN-1916-J-AM-CHEM-SOC-V38-P762 LIN CD-1986-ADV-ATOM-MOL-PHYS-V22-P77 LIN CD-1995-PHYS-REP-V257-P1 LIN CD-1984-PHYS-REV-A-V29-P1019 LIN CD-1993-REV-FUNDAMENTAL-PROC-P357 LITTLEWOOD DE-1950-THEORY-GROUP-CHARACT-P236 LOESER JG-1993-DIMENSIONAL-SCALING-P389 LOESER JG-1994-J-CHEM-PHYS-V100-P5036 LOESER JG-1991-J-CHEM-PHYS-V95-P4525 LOESER JG-1987-J-CHEM-PHYS-V86-P2114 LOESER JG-1987-J-CHEM-PHYS-V86-P3512 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1986-J-CHEM-PHYS-V84-P3882 LOESER JG-1986-J-CHEM-PHYS-V84-P3893 LOESER JG-1985-J-PHYS-CHEM-US-V89-P3444 LOPEZCABRERA M-1993-J-PHYS-CHEM-US-V97-P2467 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 LOUCK JD-1960-J-MOL-SPECTROSCOPY-V4-P285 LOUCK JD-1960-J-MOL-SPECTROSCOPY-V4-P334 LOUCK JD-1960-J-MOL-SPECTRY-V4-P298 MALUENDES SA-1986-PHYS-REV-D-V34-P1835 MARCH NH-1985-J-MATH-PHYS-V26-P554 MARCH NH-1986-PHYS-REV-A-V34-P5106 MARCH NH-1984-PHYS-REV-A-V30-P2936 MATHEWS J-1970-MATH-METHODS-PHYSICS MESSIAH A-1966-QUANTUM-MECH-V2 MIRAMONTES JL-1984-NUOVO-CIMENTO-B-V84-P10 MLODINOW LD-1981-ANN-PHYS-NEW-YORK-V131-P1 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MORALES DA-1989-CHEM-PHYS-LETT-V161-P253 MORENO G-1987-J-PHYS-B-ATOM-MOL-PH-V17-P21 MORGAN JD-1993-DIMENSIONAL-SCALING-P336 MULLER J-1994-PHYS-REV-A-V49-P2470 MULLER J-1992-PHYS-REV-A-V45-P1471 MUR VD-1987-JETP-LETT+-V45-P410 MUR VD-1990-SOV-J-NUCL-PHYS+-V51-P249 MUR VD-1988-SOV-J-NUCL-PHYS+-V47-P444 MUR VD-1990-SOV-PHYS-JETP-V70-P16 MUR VD-1990-SOV-PHYS-JETP-V70-P975 MURTAZA G-1973-J-MATH-PHYS-V14-P1196 MUSTAFA O-1993-J-PHYS-CONDENS-MATT-V5-P1333 MUSTAFA O-1993-J-QUANT-SPECTROSC-RA-V49-P65 MUSTAFA O-1994-PHYS-REV-A-V50-P2926 MUSTAFA O-1991-PHYS-REV-A-V44-P4142 MUSTAFA O-1991-PHYS-REV-A-V43-P5787 NIETO MM-1979-AM-J-PHYS-V47-P1067 NORMAND JM-1982-J-PHYS-A-MATH-GEN-V15-P1437 NORMAND JM-1980-LIE-GROUP-ROTATIONS PADE H-1892-ANN-ECOLE-NORMALE-V9-P1 PAGNAMENTA A-1986-PHYS-REV-D-V34-P3528 PANJA MM-1993-PHYS-REV-A-V42-P106 PANJA MM-1988-PHYS-REV-A-V38-P3937 PAPANICOLAOU N-1985-J-PHYS-G-NUCL-PARTIC-V11-P149 PAPP E-1988-PHYS-REV-A-V38-P2158 PAPP E-1987-PHYS-REV-A-V36-P3550 POPOV VS-1994-JETP-LETT+-V59-P158 POPOV VS-1985-JETP-LETT+-V41-P539 POPOV VS-1994-PHYS-LETT-A-V193-P159 POPOV VS-1994-PHYS-LETT-A-V193-P165 POPOV VS-1993-PHYS-LETT-A-V173-P63 POPOV VS-1993-PHYS-LETT-A-V172-P193 POPOV VS-1991-PHYS-LETT-A-V157-P185 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 POPOV VS-1992-SOV-J-NUCL-PHYS-V54-P968 POPOV VS-1986-SOV-J-NUCL-PHYS+-V44-P714 RAPOSO EP-1991-AM-J-PHYS-V59-P633 RICHTER K-1992-J-PHYS-B-AT-MOL-OPT-V25-P3929 RICHTER K-1991-J-PHYS-B-AT-MOL-OPT-V24-PL565 RICHTER K-1990-PHYS-REV-LETT-V65-P1965 RICHTMYER RD-1978-PRINCIPLES-ADV-MATH-V1-PCH5 ROBINSON GD-1961-REPRESENTATION-THEOR-V2 ROMAN P-1975-SOME-MODERN-MATH-PHY-V1-P139 ROST JM-1991-J-PHYS-B-AT-MOL-OPT-V24-P2455 ROST JM-1991-J-PHYS-B-AT-MOL-OPT-V24-P4293 ROST JM-1993-J-PHYS-CHEM-US-V97-P2461 ROST JM-1992-PHYS-REV-A-V46-P2410 ROY B-1987-J-PHYS-A-MATH-GEN-V20-P3051 ROY B-1986-PHYS-REV-A-V34-P5108 ROYCHOUDHURY R-1989-PHYS-REV-A-V39-P5523 ROYCHOUDHURY R-1988-PHYS-REV-A-V37-P2309 RUDNICK J-1987-J-PHYS-A-MATH-GEN-V20-P971 RUDNICK J-1986-J-PHYS-A-MATH-GEN-V19-PL191 RUDNICK J-1987-SCIENCE-V237-P384 SCHULTZ DR-1994-PHYS-REV-A-V50-P1348 SCHWARTZ C-1961-PHYSICAL-REVIEW-V123-P1700 SEVER R-1988-PHYS-REV-A-V37-P3158 SEVER R-1987-PHYS-REV-A-V36-P1045 SEVER R-1987-PHYS-REV-A-V35-P2725 SHAFER RE-1972-SIAM-J-NUMER-ANAL-V11-P447 SHARMA NL-1986-J-MATH-PHYS-V27-P1618 SINHAROY M-1984-J-PHYS-A-MATH-GEN-V17-PL687 STANLEY HE-1968-PHYS-REV-V176-P718 STEPANOV SS-1991-SOV-PHYS-JETP-V73-P227 STOLL RR-1952-LINEAR-ALGEBRA-MATRI-P151 SUKHATME U-1983-PHYS-REV-D-V28-P418 SUKHATME UP-1986-PHYS-REV-D-V33-P1166 SUNG SM-1993-J-PHYS-CHEM-US-V97-P2479 TALMAN JD-1968-SPECIAL-FUNCTIONS-GR TAN AL-1993-DIMENSIOAL-SCALING-C-P230 TANG AZ-1987-PHYS-REV-A-V35-P911 TOWNES CH-1955-MICROWAVE-SPECTROSCO-P300 TRAYNOR CA-1993-J-PHYS-CHEM-US-V97-P2464 VAINBERG VM-1987-JETP-LETT+-V46-P178 VAINBERG VM-1987-JETP-LETT+-V46-P225 VAINBERG VM-1986-JETP-LETT+-V44-P9 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470 VAINBERG VM-1988-THEOR-MATH-PHYS+-V74-P269 VAINBERG VM-1987-ZH-EKSP-TEOR-FIZ+-V66-P258 VALONE SM-1994-INT-J-QUANTUM-CHEM-V49-P591 VANDERMERWE PD-1985-J-CHEM-PHYS-V82-P5293 VANDERMERWE PD-1984-J-CHEM-PHYS-V81-P5976 VANDERMERWE PD-1989-PHYS-REV-A-V40-P1785 VANDERMERWE PD-1986-PHYS-REV-A-V34-P3452 VANDERMERWE PD-1986-PHYS-REV-D-V33-P3383 VANDERMERWE PD-1984-PHYS-REV-D-V30-P1596 VANDERMERWE PDT-1987-PHYS-REV-A-V36-P3446 VANDERMERWE PI-1983-LETT-NUOVO-CIMENTO-V37-P86 VARSHNI YP-1993-CAN-J-PHYS-V71-P122 VARSHNI YP-1994-CHEM-PHYS-V188-P197 VARSHNI YP-1989-PHYS-REV-A-V40-P2180 VARSHNI YP-1988-PHYS-REV-A-V38-P1595 VARSHNI YP-1987-PHYS-REV-A-V36-P3009 WATSON DK-1995-PHYS-REV-A-V51-PR5 WEISSBLUTH M-1978-ATOMS-MOL WEN ZY-1985-J-MATH-PHYS-V26-P396 WEYL H-1939-CLASSICAL-GROUPS WEYL H-1950-THEORY-GROUPS-QUANTU WILSON KG-1983-REV-MOD-PHYS-V55-P583 WINTGEN D-1992-CHAOS-V2-P19 WINTGEN D-1994-PROG-THEOR-PHYS-SUPP-V116-P121 WITTEN E-1980-NATO-ADV-STUDY-I-S-B-V59 WITTEN E-1980-PHYS-TODAY-V33-P38 WOLBARST AB-1977-SYMMETRY-QUANTUM-SYS-P68 WYBOURNE BG-1974-CLASSICAL-GROUPS-PHY-PCH15 YAFFE LG-1983-PHYS-TODAY-V36-P50 YAFFE LG-1982-REV-MOD-PHYS-V54-P407 YANEZ RJ-1994-PHYS-REV-A-V50-P3065 ZENG GJ-1994-PHYS-REV-A-V50-P4373 ZHEN Z-1993-DIMENSIONAL-SCALING-P83
Source item page count:	53
Publication Date:	NOV 1
IDS No.:	VR915
29-char source abbrev:	ANN PHYS N Y

Record 28 of 74
Author(s):	Dunn M; Watson DK
Title:	Continuation of the wave function for higher angular momentum states to D dimensions .2. Elimination of linear dependencies
Source:	ANNALS OF PHYSICS 1996, Vol 251, Iss 2, pp 319-336
No. cited references:	50
Addresses:	Dunn M, UNIV OKLAHOMA, DEPT PHYS & ASTRON, NORMAN, OK 73019.
KeywordsPlus:	MOLECULAR-ORBITAL DESCRIPTION; EXCITED 2-ELECTRON ATOMS; BARRIER STARK RESONANCES; PERTURBATION-THEORY; SCHRODINGER-EQUATION; VARIABLE DIMENSIONALITY; ELECTRONIC-STRUCTURE; QUANTUM-MECHANICS; HYDROGEN-ATOM; GROUND-STATE
Abstract:	In a previous paper the authors have developed a finite expansion for the wave function which allows the methods of dimensional scaling to be applied to higher angular momentum states. The terms in the expansion, though, are not necessarily linearly independent and so the expansion requires a little refining. The sources of linear dependence in the expansion for the wave function are explored and protocols for dealing with them are presented. (C) 1996 Academic Press, Inc.
Cited references:	ADER JP-1983-PHYS-LETT-A-V97-P178 BOERNER H-1963-REPRESENTATIONS-GROU BOTTCHER C-1994-PHYS-REV-A-V49-P1714 CHATTERJEE A-1990-PHYS-REP-V186-P249 CHISHOLM CDH-1976-GROUP-THEORETICAL-TE-PCH8 DUNN M-1996-ANN-PHYS-NEW-YORK-V251-P266 DUNN M-IN-PRESS-FEW-BODY-SY DUNN M-1994-J-CHEM-PHYS-V101-P5987 DUNN M-1993-J-PHYS-CHEM-US-V97-P2457 DUNN M-UNPUB-LARGE-DIMENSIO FRANTZ DD-1988-CHEM-PHYS-V126-P59 GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1995-PHYS-REV-LETT-V74-P658 GONZALEZ A-1992-FEW-BODY-SYST-V13-P105 GONZALEZ A-1991-FEW-BODY-SYST-V10-P43 GONZALEZ A-1990-FEW-BODY-SYST-V8-P73 GONZALEZ A-1993-J-PHYS-B-AT-MOL-OPT-V26-P1253 GONZALEZ A-1988-SOV-PHYS-LEBEDEV-I-R-V7-P65 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 GOODSON DZ-1991-PHYS-REV-A-V44-P97 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 GOSCINSKI O-1986-INT-J-QUANTUM-CHEM-V29-P897 HAMERMESH M-1989-GROUP-THEORY-ITS-APP-V4-PCH10 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 HERSCHBACK DR-1993-DIMENSIONAL-SCALING KAIS S-1994-INT-J-QUANTUM-CHEM-V49-P657 KAIS S-1994-J-CHEM-PHYS-V100-P4367 KAIS S-1993-J-CHEM-PHYS-V99-P5184 LOESER JG-1994-J-CHEM-PHYS-V100-P5036 LOESER JG-1987-J-CHEM-PHYS-V86-P3512 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOPEZCABRERA M-1993-J-PHYS-CHEM-US-V97-P2467 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MALUENDES SA-1986-PHYS-REV-D-V34-P1835 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 POPOV VS-1994-JETP-LETT+-V59-P158 POPOV VS-1994-PHYS-LETT-A-V193-P159 POPOV VS-1993-PHYS-LETT-A-V173-P63 POPOV VS-1990-PHYS-LETT-A-V149-P425 ROST JM-1992-PHYS-REV-A-V46-P2410 RUTHERFORD DE-1948-SUBSTITUTIONAL-ANAL-P21 SCHULTZ DR-1994-PHYS-REV-A-V50-P1348 SCHWARTZ C-1961-PHYSICAL-REVIEW-V123-P1700 STEPANOV SS-1991-SOV-PHYS-JETP-V73-P227 VAINBERG VM-1988-THEOR-MATH-PHYS+-V74-P269 WEYL H-1939-CLASSICAL-GROUPS
Source item page count:	18
Publication Date:	NOV 1
IDS No.:	VR915
29-char source abbrev:	ANN PHYS N Y

Record 29 of 74
Author(s):	Fernandez FM
Title:	Direct calculation of Stark resonances in hydrogen
Source:	PHYSICAL REVIEW A 1996, Vol 54, Iss 2, pp 1206-1209
No. cited references:	28
Addresses:	Fernandez FM, NATL UNIV LA PLATA, FAC CIENCIAS EXACTAS, CEQUINOR, CALLE 47 & 115, CASILLA CORREO 962, RA-1900 LA PLATA, ARGENTINA.
KeywordsPlus:	PERTURBATION-THEORY; ENERGY EIGENVALUES; ANHARMONIC-OSCILLATORS; SCHRODINGER-EQUATION; ELECTRIC-FIELD; ATOM; APPROXIMANTS; IONIZATION; SERIES
Abstract:	We propose an alternative way of calculating the resonances of the Stark effect in hydrogen. The method is based on a rational approximation of the logarithmic derivative of the eigenfunction, and leads to a quantisation condition for the complex energies of the metastable states. We present accurate results for the ground and some excited states for several field intensities.
Cited references:	ADAMS G-1994-ALGEBRAIC-APPROACH-S-P158 ALEXANDER MH-1969-PHYS-REV-V178-P34 BEKENSTEIN JD-1969-PHYS-REV-V188-P130 BENASSI L-1980-J-PHYS-B-AT-MOL-OPT-V13-P911 BRANDAS E-1977-PHYS-REV-A-V16-P2207 CERJAN C-1978-INT-J-QUANTUM-CHEM-V14-P393 DAMBURG RJ-1976-J-PHYS-B-AT-MOL-OPT-V9-P3149 FERNANDEZ FM-1989-CAN-J-PHYS-V67-P931 FERNANDEZ FM-IN-PRESS-J-PHYS-A FERNANDEZ FM-1995-J-PHYS-A-MATH-GEN-V28-P4043 FERNANDEZ FM-1993-J-PHYS-A-MATH-GEN-V26-P7169 FERNANDEZ FM-1995-PHYS-LETT-A-V203-P275 FERNANDEZ FM-1992-PHYS-LETT-A-V166-P173 FERNANDEZ FM-1993-PHYS-REV-A-V48-P4170 FERNANDEZ FM-1989-PHYS-REV-A-V40-P6149 FERNANDEZ FM-1989-PHYS-REV-A-V39-P1605 FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 FROELICH P-1976-INT-J-QUANTUM-CHEM-S-V10-P353 FROELICH P-1975-PHYS-REV-A-V12-P1 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 HEHENBERM-1974-PHYS-REV-A-V10-P1494 HIRSCHFELDER JO-1971-J-CHEM-PHYS-V55-P1395 MAQUET A-1983-PHYS-REV-A-V27-P2946 MARTIN A-1959-NUOVO-CIMENTO-V14-P403 POPOV VS-1990-PHYS-LETT-A-V149-P418 REINHARDT WP-1976-INT-J-QUANTUM-CHEM-S-V10-P359 RICE MH-1962-J-OPT-SOC-AM-V52-P239 SILVERMAN JN-1988-CHEM-PHYS-LETT-V153-P61
Source item page count:	4
Publication Date:	AUG
IDS No.:	VD676
29-char source abbrev:	PHYS REV A

Record 30 of 74
Author(s):	Ratis YL; Gareev FA
Title:	Asymptotic estimates of the decay widths of quasistationary states
Source:	PHYSICS OF ATOMIC NUCLEI 1996, Vol 59, Iss 6, pp 960-967
No. cited references:	38
Addresses:	Ratis YL, JOINT INST NUCL RES, DUBNA 141980, RUSSIA.
Abstract:	A new integral formalism for calculating the decay widths of quasistationary states is constructed without recourse to the assumption that a barrier-penetrability factor is small. The method of steepest descent is used to obtain asymptotic expressions for the widths of short-lived quasistationary states. On the basis of these expressions, the widths of Pb nuclei and of baryon and dibaryon resonances are calculated within a unified approach. The theory is shown to be in fairly goad agreement with experimental data. A natural explanation is given for the smallness of the widths of low-lying resonances.
Cited references:	AIZENBERG J-1972-MICROSCOPIC-THEORY-N BAUTRIN VN-1991-1750-LNPI-RUSS-AC-SC BAZ AI-1971-RASSEYANIE-REAKTSII BROWNE E-1986-TABLE-RADIOACTIVE-IS BUCK B-1990-PHYS-REV-LETT-V65-P2975 CONDON EU-1929-PHYSICAL-REVIEW-V33-P127 ERICSON T-1988-PIONS-NUCLEI FLUGGE F-1957-STRUCTURE-ATOMIC-NUC GAMOW G-1928-Z-PHYS-V51-P204 GAMOW G-1928-Z-PHYSIK-V52-P510 GAREEV FA-1992-E292474-JINR-P272 GAREEV FA-1993-E293426-JINR GAREEV FA-1994-FIZ-ELEM-CHASTITS-AT-V25-P855 GAREEV FA-1994-P-14-INT-IUPAP-C-FEW-P365 GAREEV FA-1994-P-7-INT-C-NUCL-REACT-P621 GAREEV FA-1992-P-INT-C-NUCL-STRUCT-P272 GAREEV FA-1993-P-WORKSH-GROSS-PROP-V21-P197 GEIGER H-1911-PHILOS-MAG-V22-P613 KADMENSKY SG-1985-ALFA-RASPAD-RODSTVEN KADMENSKY SG-1978-YAD-FIZ-V27-P630 KADMENSKY SG-1978-YAD-FIZ-V27-P906 LANE AM-1958-REV-MOD-PHYS-V30-P257 LOCHER MF-1986-ADV-NUCL-PHYS-V17-P42 MONTANET L-1994-PHYS-REV-D-1-V50 MUR VD-1990-JETP-LETT+-V51-P499 MUR VD-1991-PHYS-LETT-A-V157-P185 POPOV VS-1991-ZH-EKSP-TEOR-FIZ+-V100-P20 RATIS YL-1992-E292158-JINR RATIS YL-1992-E2923-JINR RATIS YL-1993-P-3-INT-S-WEAK-EL-IN-P795 RATIS YL-1992-P-WORKSH-GROSS-PROP-V20 TATISCHEFF B-1991-P-10-INT-SEM-HIGH-EN-P177 TATISCHEFF B-1994-P-12-INT-SEM-HIGH-EN TROYAN YA-1994-FIZ-ELEM-CHASTITS-AT-V22-P603 TROYAN YA-1991-P-10-INT-SEM-HIGH-EN-P149 TROYAN YA-1993-YAD-FIZ-V56-P191 VAINSHTEIN LA-1966-OTKRYTYE-REZONATORY YOKOSAWA A-1985-J-PHYS-SOC-JPN-S-V55-P251
Source item page count:	8
Publication Date:	JUN
IDS No.:	UW595
29-char source abbrev:	PHYS ATOM NUCL-ENGL TR

Record 31 of 74
Author(s):	Germann TC
Title:	Use of dimension-dependent potentials for quasibound states
Source:	JOURNAL OF CHEMICAL PHYSICS 1996, Vol 104, Iss 13, pp 5100-5108
No. cited references:	70
Addresses:	Germann TC, UNIV CALIF BERKELEY, DEPT CHEM, BERKELEY, CA 94720.
KeywordsPlus:	COMPLEX ENERGY EIGENVALUES; PERTURBATION-THEORY; 2-ELECTRON ATOMS; VARIABLE DIMENSIONALITY; QUANTUM-MECHANICS; 1/N EXPANSION; STRONG-FIELD; 1/N-EXPANSION; INTERPOLATION; RESONANCES
Abstract:	Dimensional perturbation theory is applied to the calculation of complex energies for quasibound (resonance) eigenstates, using a modified dimension-dependent potential so that the infinite-dimensional limit better reflects the physical (three-dimensional) nature of the resonant eigenstate. Using the previous approach of retaining the D=3 form of the potential for all spatial dimension D, highly accurate results are obtained via Pade-Borel summation of the expansion coefficients when they are complex, but a lesser degree of convergence is found when quadratic Pade summation is applied to real expansion coefficients. The present technique of using a dimension-dependent potential allows complex expansion coefficients to be obtained in all cases, and is demonstrated to provide a marked improvement in convergence. We illustrate this approach on the Lennard-Jones potential and the hydrogen atom in an electric field. (C) 1996 American Institute of Physics.
Cited references:	1978-INT-J-QUANTUM-CHEM-V14 ADER JP-1983-PHYS-LETT-A-V97-P178 ARTECA GA-1990-LECT-NOTES-CHEM-V53-P126 ATABEK O-1981-CHEM-PHYS-LETT-V78-P13 ATABEK O-1980-MOL-PHYS-V40-P1107 BENDER CM-1978-ADV-MATH-METHODS-SCI BLEIL R-1995-INT-J-QUANTUM-CHEM-S-V29-P349 BLEIL R-1995-J-CHEM-PHYS-V103-P6529 CASHION JK-1963-J-CHEM-PHYS-V39-P1872 CERJAN C-1978-INT-J-QUANTUM-CHEM-V14-P393 COHEN JM-IN-PRESS-INT-J-QUANT CONNOR JNL-1983-J-CHEM-PHYS-V78-P6161 COOLEY JW-1961-MATH-COMPUTATION-V15-P363 DOOLEN GD-1978-INT-J-QUANTUM-CHEM-V14-P523 DOOLEN GD-1975-J-PHYS-B-AT-MOL-OPT-V8-P525 DUNN M-1994-J-CHEM-PHYS-V101-P5987 FERNANDEZ FM-1995-J-MATH-PHYS-V36-P3922 FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 FRIEDRICH H-1991-THEORETICAL-ATOMIC-P GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GERMANN TC-1995-J-PHYS-B-AT-MOL-OPT-V28-PL531 GERMANN TC-1995-PHYS-REV-LETT-V74-P658 GERMANN TC-1995-THESIS-HARVARD-U GOODSON DZ-1992-DIMENSIONAL-SCALING GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 GOODSON DZ-1986-THESIS-HARVARD-U GRAFFI S-1971-NUOVO-CIMENTO-B-V4-P313 GRAFFI S-1970-PHYSICS-LETTERS-B-V32-P631 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HO YK-1983-PHYS-REP-V99-P1 JUNKER BR-1982-ADV-ATOM-MOL-PHYS-V18-P207 KAIS S-1994-INT-J-QUANTUM-CHEM-V49-P657 KAIS S-1995-J-CHEM-PHYS-V102-P7472 KAIS S-1994-J-CHEM-PHYS-V100-P4367 KAIS S-1993-J-CHEM-PHYS-V99-P5184 KAIS S-1993-J-CHEM-PHYS-V98-P3990 KILLINGBECK J-1987-J-PHYS-A-MATH-GEN-V20-P601 LANDAU LD-1977-QUANTUM-MECHANICS LEROY RJ-1978-J-CHEM-PHYS-V69-P3622 LOESER JG-1994-J-CHEM-PHYS-V100-P5036 LOPEZCABRERA M-1993-J-PHYS-CHEM-US-V97-P2467 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 LOPEZCABRERA M-1991-THESIS-U-MICHIGAN MANDELSHTAM VA-1993-PHYS-REV-LETT-V70-P1932 MULLER J-1994-PHYS-REV-A-V49-P2470 PADE H-1892-ANN-ECOLE-NORMALE-V9-P1 POPOV VS-1992-DIMENSIONAL-SCALING POPOV VS-1994-PHYS-LETT-A-V193-P165 POPOV VS-1993-PHYS-LETT-A-V172-P193 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 POPOV VS-1994-SOV-PHYS-JETP-V71-P303 PRESS WH-1992-NUMERICAL-RECIPES REINHARDT WP-1982-ANNU-REV-PHYS-CHEM-V33-P224 REINHARDT WP-1982-INT-J-QUANTUM-CHEM-V21-P133 REINHARDT WP-1988-MATH-METHODS-COMPUTA-P41 ROST JM-1993-J-PHYS-CHEM-US-V97-P2461 SHAFER RE-1972-SIAM-J-NUMER-ANAL-V11-P447 TAYLOR HS-1970-ADVAN-CHEM-PHYS-V18-P91 TRAYNOR CA-1993-J-PHYS-CHEM-US-V97-P2464 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470 VAINBERG VM-1988-THEOR-MATH-PHYS+-V74-P269 WATSON DK-1995-PHYS-REV-A-V51-PR5 ZHENG Z-1992-DIMENSIONAL-SCALING
Source item page count:	9
Publication Date:	APR 1
IDS No.:	UD669
29-char source abbrev:	J CHEM PHYS

Record 32 of 74
Author(s):	Herschbach DR
Title:	Dimensional scaling and renormalization
Source:	INTERNATIONAL JOURNAL OF QUANTUM CHEMISTRY 1996, Vol 57, Iss 3, pp 295-308
No. cited references:	51
Addresses:	Herschbach DR, HARVARD UNIV, DEPT CHEM, 12 OXFORD ST, CAMBRIDGE, MA 02138.
KeywordsPlus:	MOLECULAR-ORBITAL DESCRIPTION; PERTURBATION-THEORY; 2-ELECTRON ATOMS; 1/D EXPANSION; CORRELATION ENERGIES; BODY PROBLEM; STATES; LIMIT; SYMMETRY; DENSITY
Abstract:	Chief features of dimensional scaling methods are exemplified by briefly reviewing prototypical applications and recent developments. The pseudoclassical large-D limit usually can be evaluated exactly regardless of the magnitude, nature, and number of strong, nonseparable dynamical interactions. Often, this limit can be accurately Linked to D = 3 by perturbation or interpolation methods. This is because the dimension dependence of many-body effects tends to be smooth and mild when calibrated by appropriate one- or few-body problems. A simple renormalization procedure applied to atoms with up N similar to 100 electrons yields a major part of the correlation energy. From Hartree-Fock input, a renormalized nuclear charge is determined which renders the dimensionally scaled energy at D --> infinity a good approximation to that for D = 3 with the actual Z. Prospects are discussed for other means to exploit dimensional scaling, including an analogous renormalization procedure for molecules. (C) 1996 John Wiley & Sons, Inc.
Cited references:	AVERY J-1995-STRUCTURE-DYNAMICS-A-P133 AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BELOV AA-1988-SOV-PHYS-JETP-V67-P2413 BELOV AA-1989-THEOR-MATH-PHYS+-V81-P1294 BELOV AA-1990-ZH-EKSP-TEOR-FIZ+-V98-P25 CHAKRAVORTY SJ-1993-PHYS-REV-A-V47-P3649 DOREN DJ-1987-J-CHEM-PHYS-V87-P433 DUNN M-1994-J-CHEM-PHYS-V101-P5987 DUNN M-1993-J-PHYS-CHEM-US-V97-P2457 FRANTZ DD-1990-J-CHEM-PHYS-V92-P6668 GERMANN TC-1994-COMPUT-PHYS-V8-P712 GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GERMANN TC-1995-PHYS-REV-LETT-V74-P658 GOLDSCHMIDT YY-1993-NUCL-PHYS-B-V393-P507 GONZALEZ A-1993-J-PHYS-B-AT-MOL-OPT-V26-P1253 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 GOODSON DZ-1992-PHYS-REV-A-V46-P5428 GOODSON DZ-1991-PHYS-REV-A-V43-P4617 HERSCHBACH D-1993-P-AM-PHILOS-SOC-V137-P532 HERSCHBACH DR-1993-DIMENSIONAL-SCALING HOLAS A-1991-J-PHYS-A-MATH-GEN-V24-P4249 KAIS S-1992-CHEM-PHYS-V161-P393 KAIS S-1994-INT-J-QUANTUM-CHEM-V49-P657 KAIS S-1994-J-CHEM-PHYS-V100-P4367 KAIS S-1993-J-CHEM-PHYS-V99-P417 KAIS S-1993-J-CHEM-PHYS-V99-P5194 KAIS S-1993-J-CHEM-PHYS-V98-P3990 KAIS S-1991-J-CHEM-PHYS-V95-P9028 KAIS S-1989-J-CHEM-PHYS-V91-P7791 KAIS S-1994-J-PHYS-CHEM-US-V98-P11015 KAIS S-1993-J-PHYS-CHEM-US-V97-P2453 KARPLUS M-1990-J-PHYS-CHEM-US-V99-P5435 LEVY M-1994-INT-J-QUANTUM-CHEM-V49-P539 LOESER JG-1994-J-CHEM-PHYS-V100-P5036 LOESER JG-1991-J-CHEM-PHYS-V95-P4525 LOESER JG-1987-J-CHEM-PHYS-V86-P3512 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOPEZCABRERA M-1993-J-PHYS-CHEM-US-V97-P2467 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MILLER WH-1973-J-CHEM-PHYS-V58-P1664 POPOV VS-1993-PHYS-LETT-A-V172-P193 ROST JM-1993-J-PHYS-CHEM-US-V97-P2461 ROST JM-1992-PHYS-REV-A-V46-P2410 RUDNICK J-1987-SCIENCE-V237-P384 STRAND MP-1979-J-CHEM-PHYS-V70-P3812 SUNG SM-1993-J-PHYS-CHEM-US-V97-P2479 TRAYNOR CA-1993-J-PHYS-CHEM-US-V97-P2464 VALONE SM-1994-INT-J-QUANTUM-CHEM-V49-P591 YAFFE LG-1982-REV-MOD-PHYS-V54-P407
Source item page count:	14
Publication Date:	FEB 5
IDS No.:	TM715
29-char source abbrev:	INT J QUANTUM CHEM

Record 33 of 74
Author(s):	PANCHANAN S; ROY B; ROYCHOUDHURY R
Title:	GROUP THEORETIC APPROACH FOR A DIRAC PARTICLE IN COULOMB-LIKE POTENTIALS
Source:	JOURNAL OF PHYSICS A-MATHEMATICAL AND GENERAL 1995, Vol 28, Iss 22, pp 6467-6477
No. cited references:	43
Addresses:	PANCHANAN S, INDIAN STAT INST, PHYS & APPL MATH UNIT, CALCUTTA 700035, W BENGAL, INDIA.
KeywordsPlus:	LARGE-N EXPANSION; RELATIVISTIC PERTURBATION-THEORY; SCALAR POTENTIALS; SPIN-1/2 PARTICLE; 1/N EXPANSION; EQUATION; EIGENVALUES; VECTOR
Abstract:	The energy levels of the Dirac equation with a Kohn-Sham (KS) potential are obtained using algebraic perturbation theory based on the dynamical group structure SO(2, 1) without making any non-relativistic approximation. It has been shown that this formalism reproduces the exact analytical result for the eigenvalues of the Dirac equation with both vector and scalar Coulomb potentials. The lowest-order results obtained from the analytical formulae are found to be in excellent agreement with exact numerical results.
Cited references:	AHARONOV Y-1980-PHYS-REV-LETT-V44-PE619 AHARONOV Y-1979-PHYS-REV-LETT-V43-PE176 AHARONOV Y-1979-PHYS-REV-LETT-V42-P1582 ATAG S-1989-J-MATH-PHYS-V30-P696 AU CK-1980-PHYS-REV-A-V20-P1820 AU CK-1979-PHYS-REV-A-V20-P2245 BAGROV VG-1977-EXACT-SOLUTIONS-RELA BARUT AO-1971-DYNAMICAL-GROUPS-GEN BARUT AO-1971-J-MATH-PHYS-V12-P841 BARUT AO-1977-J-PHYS-A-MATH-GEN-V10-P1243 BARUT AO-1973-SIAM-J-APPL-MATH-V25-P247 BECHLER A-1977-ANN-PHYS-NEW-YORK-V108-P49 BEDNAR M-1973-ANN-PHYS-NEW-YORK-V75-P305 BOHM A-DYNAMICAL-GROUPS-SPE-V2 BOHM A-DYNAMICAL-GROUPS-SPE-V1 CHATTERJEE A-1986-J-MATH-PHYS-V27-P2331 FLUGGE S-1974-PRACTICAL-QUANTUM-ME-V1-P175 FOCK VA-1978-FUNDAMENTALS-QUANTUM GERRY CC-1983-PHYS-LETT-A-V95-P481 GERRY CC-1981-PHYS-REV-D-V23-P503 HALL RL-1985-J-MATH-PHYS-V26-P1779 KLEINERT H-1968-LECTURES-THEORETIC-B-V10 LIBERMAN DA-1965-PHYS-REV-V137-PA27 MATHYS P-1988-PHYS-REV-A-V36-P168 MCEMNAN J-1977-PHYS-REV-A-V16-P1768 MIKHAILOV AI-1968-SOV-PHYS-JETP-V27-P95 MIRAMONTES JL-1984-NUOVO-CIMENTO-B-V84-P10 MITTER H-1984-J-PHYS-A-MATH-GEN-V17-P1215 MOSHINSKY M-1989-J-PHYS-A-MATH-GEN-V22-PL817 NIETO MM-1979-AM-J-PHYS-V47-P1067 PANJA MM-1992-PHYS-REV-A-V45-P1523 PANJA MM-1990-PHYS-REV-A-V42-P106 PANJA MM-1988-PHYS-REV-A-V38-P3937 PAPP E-1991-ANN-PHYS-LEIPZIG-V48-P319 ROGERS GW-1984-PHYS-REV-A-V30-P35 ROY B-1990-J-PHYS-A-MATH-GEN-V23-P3555 ROY B-1990-J-PHYS-A-MATH-GEN-V23-P5095 ROYCHOUDHURY R-1987-J-PHYS-A-V21-PL1083 ROYCHOUDHURY R-1989-PHYS-REV-A-V39-P5523 RUTKOWSKI A-1986-J-PHYS-B-AT-MOL-OPT-V19-P149 RUTKOWSKI A-1986-J-PHYS-B-AT-MOL-OPT-V19-P3431 SERGEEV AV-1984-SOV-J-NUCL-PHYS+-V39-P731 TUTIK RS-1992-J-PHYS-A-MATH-GEN-V25-PL413
Source item page count:	11
Publication Date:	NOV 21
IDS No.:	TJ578
29-char source abbrev:	J PHYS-A-MATH GEN

Record 34 of 74
Author(s):	SHUBOV MA
Title:	STARK QUANTUM-DEFECT FOR HIGH RYDBERG STATES OF 3-DIMENSIONAL SCHRODINGER OPERATOR WITH SCREENED COULOMB POTENTIAL
Source:	NUOVO CIMENTO DELLA SOCIETA ITALIANA DI FISICA B-GENERAL PHYSICS RELATIVITY ASTRONOMY AND MATHEMATICAL PHYSICS AND METHODS 1995, Vol 110, Iss 9, pp 1057-1092
No. cited references:	34
Addresses:	SHUBOV MA, TEXAS TECH UNIV, LUBBOCK, TX 79409.
KeywordsPlus:	IONIZATION THRESHOLD; PERTURBATION-THEORY; SCATTERING; FIELD
Abstract:	We consider a 1-particle 3-dimensional Schrodinger operator with Coulomb potential perturbed by a compactly supported function q(x)(x is an element of R(3)) and by an external electric field. In contrast with the usual treatment of Stark effect, we assume that the electric field is homogeneous only in a bounded region and is zero outside this region. Both the region and the perturbation q(x) are assumed to have a special parabolic symmetry. We give a rigorous derivation of an asymptotic formula for the discrete spectrum of the problem. This formula describes the splitting of the high Rydberg energy levels of an alkali-like atom in an electric field. We give an explicit formula for the <<Stark quantum defect>> in terms of q(x) and the strength epsilon of the electric field. We give, also, explicit expressions for zero-order, linear and quadratic terms in the asymptotic expansion of the quantum defect with respect to epsilon --> 0. The derivation of the above-mentioned results is nonperturbative. We suggest a method which allows to carry out a very detailed asymptotic analysis of the solutions of the corresponding Schrodinger equation. The main formulas of this work can be used for numerical computations of the quantum defect. This work can, also, be considered as a necessary technical step towards the precise asymptotic analysis of the Stark resonances in the problem without a cut-off of the electrical field potential.
Cited references:	ABRAMOVITZ M-1972-HDB-MATH-FUNCTIONS ALLILUEV SP-1993-SOV-PHYS-JETP-V77-P701 AVRON JE-1977-COMMUN-MATH-PHYS-V52-P239 BETHE HA-1957-QUANTUM-MECHANICS-ON BHATTACHARYA M-1994-INDIAN-J-PHYS-B-V68-P17 BUHHOLTZ H-1969-CONFLUENT-HYPERGEOME FILHO OLS-1990-PHYS-REV-A-V42-P4008 GRAFFI S-1981-COMMUN-MATH-PHYS-V79-P91 GRAFFI S-1978-COMMUN-MATH-PHYS-V62-P83 HAKEN H-1993-PHYSICS-ATOMS-QUANTA HERBST IW-1978-PHYS-REV-LETT-V41-P67 HEZEL TP-1992-AM-J-PHYS-V60-P324 ITO K-1993-PHYS-REV-A-V47-P1187 KLEIN M-1990-COMMUN-MATH-PHYS-V131-P109 KOLOSOV VV-1989-J-PHYS-B-AT-MOL-OPT-V22-P833 KOLOSOV VV-1989-PHYS-LETT-A-V140-P36 KVITSINSKY AA-1990-J-MATH-PHYS-V31-P2731 LANDAU LD-1977-QUANTUM-MECHANICS LISITSA VS-1987-SOV-PHYS-USP-V30-P927 MAGNUS W-1966-FORMULAS-THEOREMS-SP NEWTON RG-1982-SCATTERING-THEORY-WA POPOV VS-1990-PHYS-LETT-A-V149-P418 REED M-1978-METHODS-MODERN-MATH-V4 RIDDEL RC-1967-PAC-J-MATH-V23-P2 SHUBOV MA-1991-INTEGR-EQUAT-OPER-TH-V14-P586 SHUBOV MA-1994-J-DIFFER-EQUATIONS-V114-P168 SHUBOV MA-1994-J-MATH-ANAL-APPL-V181-P600 SHUBOV MA-1994-J-MATH-PHYS-V35-P656 SHUBOVA MA-1988-THEORETICAL-MATH-PHY-V76-P379 SLATER LJ-1960-CONFLUENT-HYPERGEOME STEBBINGS RF-1983-RYDBERG-STATES-ATOMS TITCHMARSH EC-1958-EIGENFUNCTION-EXPANS TITCHMARSH EC-1955-J-ANAL-MATH-V4-P187 VESELIC K-1977-MATH-Z-V156-P93
Source item page count:	36
Publication Date:	SEP
IDS No.:	RX376
29-char source abbrev:	NUOVO CIMENTO B-GEN PHYS R

Record 35 of 74
Author(s):	MUR VD; POPOV VS
Title:	PERTURBATION-THEORY FOR QUASI-STATIONARY STATES
Source:	PHYSICS OF ATOMIC NUCLEI 1995, Vol 58, Iss 8, pp 1329-1341
No. cited references:	36
Addresses:	INST THEORET & EXPTL PHYS, STATE RES CTR, MOSCOW 117259, RUSSIA.
KeywordsPlus:	QUANTIZATION RULES; APPROXIMATION
Abstract:	Perturbation theory (to the first order) for quasistationary states is developed in the semiclassical approximation. Formulas for the energy shift delta E, of a resonance, as well as for the variation of its width delta Gamma due to a perturbative potential delta U, are obtained. These formulas are valid both for subbarrier and above barrier resonances. The results are illustrated using a number of potentials for which semiclassical expressions can be compared with exact solutions of the Schrodinger equation. The proposed scheme is generalized to a multidimensional case with completely separating variables.
Cited references:	ALVAREZ G-1988-PHYS-REV-A-V37-P4079 BAZ AI-1961-EIGENFUNCTION-EXPA-2 BAZ AI-1971-RASSEYANIE-REAKTSII-P320 BENDER CM-1977-PHYS-REV-D-V16-P1740 CONNOR JNL-1973-MOL-PHYS-V25-P1469 DUNHAM JL-1932-PHYS-REV-V41-P713 GALITSKII VM-1992-ZADACHI-KVANTOVOI-ME GRADSHTEYN IS-1962-TABLITSY-INTEGRALOV KESARWANI RN-1981-J-MATH-PHYS-V22-P1983 KESARWANI RN-1980-J-MATH-PHYS-V21-P90 LANDAU LD-1974-KVANTOVAYA-MEKHANIKA LURE AI-1961-ANALITICHESKAYA-MEKH MIGDAL AB-1975-KACHESTVENNYE-METODY MUR VD-1990-JETP-LETT+-V51-P499 MUR VD-1988-JETP-LETT+-V48-P67 MUR VD-1993-PISMA-ESKP-TEOR-FIZ-V57-P406 MUR VD-1978-PISMA-ESKP-TEOR-FIZ-V28-P140 MUR VD-1993-YAD-FIZ-V56-P125 MUR VD-1990-YAD-FIZ-V52-P1540 MUR VD-1993-ZH-EKSP-TEOR-FIZ+-V104-P2293 MUR VD-1988-ZH-EKSP-TEOR-FIZ+-V94-P125 PERELOMOV AM-1966-ZH-EKSP-TEOR-FIZ+-V50-P1393 POPOV VS-1991-PHYS-LETT-A-V157-P185 POPOV VS-1978-PHYS-LETT-B-V80-P68 POPOV VS-1994-PISMA-ESKP-TEOR-FIZ-V59-P64 POPOV VS-1971-PISMA-ESKP-TEOR-FIZ-V13-P261 POPOV VS-1970-PISMA-ESKP-TEOR-FIZ-V11-P254 POPOV VS-1970-YAD-FIZ-V12-P429 POPOV VS-1967-ZH-EKSP-TEO-V53-P331 POPOV VS-1970-ZH-EKSP-TEOR-FIZ-V59-P965 POPOV VS-1991-ZH-EKSP-TEOR-FIZ+-V100-P20 POPOV VS-1979-ZH-EKSP-TEOR-FIZ+-V76-P432 POPOV VS-1971-ZH-EKSP-TEOR-FIZ+-V61-P1334 PRUDNIKOV AP-1986-INTEGRALY-RYADY ZELDOVICH YB-1971-USP-FIZ-NAUK-V105-P403 ZELDOVICH YB-1960-ZH-EKSP-TEOR-FIZ-V39-P776
Source item page count:	13
Publication Date:	AUG
IDS No.:	RU385
29-char source abbrev:	PHYS ATOM NUCL-ENGL TR

Record 36 of 74
Author(s):	RAO J; LI BW
Title:	RESONANCES OF THE HYDROGEN-ATOM IN STRONG PARALLEL MAGNETIC AND ELECTRIC-FIELDS
Source:	PHYSICAL REVIEW A 1995, Vol 51, Iss 6, pp 4526-4530
No. cited references:	24
Addresses:	RAO J, CHINESE ACAD SCI, WUHAN INST PHYS, MAGNET RESONANCE & ATOM & MOLEC PHYS LAB, WUHAN 430071, PEOPLES R CHINA. CHINA CTR ADV SCI & TECHNOL, WORLD LAB, BEIJING 100080, PEOPLES R CHINA. CHINESE ACAD SCI, WUHAN INST PHYS, WUHAN 430071, PEOPLES R CHINA.
KeywordsPlus:	STATES; APPROXIMANTS; DC
Cited references:	BENASSI L-1980-J-PHYS-B-AT-MOL-OPT-V13-P911 BHATTACHARYA SK-1983-J-PHYS-B-AT-MOL-OPT-V16-PL471 CACCIANI P-1988-J-PHYS-B-AT-MOL-OPT-V21-P3499 CHU SI-1978-CHEM-PHYS-LETT-V58-P462 DAMBURG RJ-1983-RYDBERG-STATES-ATOMS-P31 DEBOOR C-1978-PRACTICAL-GUIDE-SPLI DELANDE D-1991-PHYS-REV-LETT-V25-P3237 FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 FRIEDRICH H-1983-PHYS-REV-A-V28-P1423 GLUSHKOV AV-1993-J-PHYS-B-AT-MOL-OPT-V26-PL379 JOHNSON BR-1983-PHYS-REV-LETT-V58-P2280 KLEPPNER D-1983-RYDBERG-STATES-ATOMS-P73 KOLOSOV VV-1987-J-PHYS-B-AT-MOL-OPT-V20-P2359 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P2011 LIU WY-1993-PHYS-REV-A-V47-P3151 MAQUET A-1983-PHYS-REV-A-V27-P2946 POPOV VS-1990-PHYS-LETT-A-V149-P418 RAO JG-1994-PHYS-REV-A-V50-P1916 REINHARDT WP-1982-ANNU-REV-PHYS-CHEM-V33-P223 REINHARDT WP-1976-INT-J-QUANTUM-CHEM-S-V10-P359 TELNOV DA-1989-J-PHYS-B-AT-MOL-OPT-V22-PL399 VINCKE M-1987-J-PHYS-B-AT-MOL-OPT-V20-P3335 WATERLAND RL-1987-PHYS-REV-A-V35-P5064 XI JH-1992-PHYS-REV-A-V46-P5806
Source item page count:	5
Publication Date:	JUN
IDS No.:	RC541
29-char source abbrev:	PHYS REV A

Record 37 of 74
Author(s):	KARNAKOV BM; MUR VD; POPOV VS
Title:	1/N-DECOMPOSITION OF WAVE-FUNCTIONS
Source:	ZHURNAL EKSPERIMENTALNOI I TEORETICHESKOI FIZIKI 1994, Vol 106, Iss 4, pp 976-992
No. cited references:	44
Addresses:	KARNAKOV BM, MOSCOW ENGN PHYS INST, MOSCOW 115409, RUSSIA. INT PHYS INST, MOSCOW 125040, RUSSIA. MOSCOW THEORET & EXPTL PHYS INST, MOSCOW 117259, RUSSIA.
KeywordsPlus:	SHIFTED 1/N EXPANSIONS; PERTURBATION-THEORY; QUANTUM-MECHANICS; SCHRODINGER-EQUATION; 1/N-EXPANSION; CHARMONIUM; SYSTEMS; FIELD; MODEL
Cited references:	BACKENSTOSS G-1970-ANN-REV-NUCL-SCI-V20-P467 BENDER CM-1982-PHYS-REV-A-V25-P1305 BERK DD-1980-POTENTSIALNOE-RASSEY CHATTERJEE A-1990-PHYS-REP-V186-P249 DESER S-1954-PHYSICAL-REVIEW-V96-P774 DOLGOV AD-1979-PHYS-LETT-B-V86-P185 DOREN DJ-1986-PHYS-REV-A-V34-P2654 EICHTEN E-1980-PHYS-REV-D-V21-P203 EICHTEN E-1980-PHYS-REV-D-V21-P313 EICHTEN E-1978-PHYS-REV-D-V17-P3090 GALITSKII VM-1981-TEORIYA-STOLKNOVENIY GERSTEIN SS-1977-PHYS-LETT-B-V72-P80 GODFREY S-1985-PHYS-REV-D-V32-P189 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 HERCHBACH DR-1993-DIMENSIONAL-SCALING HIKAMI S-1979-J-PHYS-A-MATH-GEN-V12-P759 IMBO T-1984-PHYS-REV-D-V29-P1669 JAFFE LG-1982-REV-MOD-PHYS-V54-P407 KARNAKOV BM-1988-ZH-EKSP-TEOR-FIZ+-V94-P65 KHEDING D-1965-VVEDENIE-METOD-FAZOV KIRZHNITS DA-1982-ZH-EKSP-TEOR-FIZ+-V82-P657 KUDRYAVTSEV AE-1979-PISMA-ZHETF-V29-P311 LAMBERT E-1969-HELV-PHYS-ACTA-V42-P667 LANDAU LD-1989-KVANTOVAYA-MEKHANIKA LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MALUENDES SA-1986-PHYS-REV-D-V34-P1835 MIGDAL AB-1975-KACHESTVENNYE-METODY MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MUR VD-1992-J-MOSC-PHYS-SOC-V2-P189 MUR VD-1987-JETP-LETT+-V45-P323 MUR VD-1976-TEOR-MAT-FIZ-V27-P204 MUR VD-1988-YAF-V47-P697 MUR VD-1990-ZH-EKSP-TEOR-FIZ+-V97-P32 POPOV VS-1985-JETP-LETT+-V41-P439 POPOV VS-1987-PHYS-LETT-A-V124-P77 POPOV VS-1991-YAD-FIZ-V54-P1582 POPOV VS-1986-YAD-FIZ-V44-P1103 POPOV VS-1992-ZH-EKSP-TEOR-FIZ+-V102-P1453 POPOV VS-1981-ZH-EKSP-TEOR-FIZ+-V80-P1271 POPOV VS-1979-ZH-EKSP-TEOR-FIZ+-V77-P1727 SUKHATME U-1983-PHYS-REV-D-V28-P418 VANDERMERWE PD-1986-PHYS-REV-D-V33-P3383 ZELDOVICH YB-1959-FTT-V1-P1637 ZELDOVICH YB-1960-USP-FIZ-NAUK-V71-P581
Source item page count:	17
Publication Date:	OCT
IDS No.:	PQ455
29-char source abbrev:	ZH EKSP TEOR FIZ

Record 38 of 74
Author(s):	KOCHETOV EA; YUKALOV VI
Title:	NEW THEORETICAL METHODS IN QUANTUM-ELECTRONICS
Source:	IZVESTIYA AKADEMII NAUK SERIYA FIZICHESKAYA 1994, Vol 58, Iss 8, pp 4-19
No. cited references:	83
Addresses:	KOCHETOV EA, MOSCOW JOINT NUCL RES INST, THEORET PHYS LAB, MOSCOW, RUSSIA.
KeywordsPlus:	SELF-SIMILAR APPROXIMATIONS; PATH-INTEGRAL APPROACH; JAYNES-CUMMINGS MODEL; OPTIMIZED PERTURBATION-THEORY; COHERENT STATES; ANHARMONIC-OSCILLATOR; SCHRODINGER-EQUATION; VARIATIONAL APPROACH; FIELD AMPLITUDE; COULOMB SYSTEM
Cited references:	ALLEN L-1978-OPTICHESKII-REZONANS ANDREEV AEV-1988-KOOPERATIVNYE-YAVLEN BALANTEKIN AB-1989-J-MATH-PHYS-V30-P274 BARS I-1983-COMMUN-MATH-PHYS-V91-P31 BARUT A-1980-TEORIYA-PREDSTAVLENI BOGOLYUBOV NN-1974-ASIMPTOTICHESKIE-MET BOSIGER P-1978-PHYS-REV-A-V18-P671 BUZANO C-1989-PHYS-REV-LETT-V62-P137 CHAKRABARTI R-1992-J-PHYS-A-MATH-GEN-V25-P6399 COOPER F-1992-PHYSICA-D-V56-P68 DECROMBRUGGHE M-1983-ANN-PHYS-NEW-YORK-V151-P99 DICKE RH-1954-PHYS-REV-V93-P99 DRAGANASCU GE-1992-PHYS-LETT-A-V170-P339 DRUMMOND PD-1980-J-PHYS-A-MATH-GEN-V13-P725 EFIMOV GV-1989-INT-J-MOD-PHYS-A-V4-P4977 ELLINAS D-1992-PHYS-REV-A-V45-P1822 EMELYANOV VI-1986-OPT-SPEKTROSK+-V60-P634 FATYGA BW-1991-PHYS-REV-D-V43-P1403 FERANCHUK ID-1984-J-PHYS-A-MATH-GEN-V17-P3111 FERANCHUK ID-1985-J-PHYS-C-SOLID-STATE-V18-P5083 FERNANDEZ FM-1991-PHYS-LETT-A-V160-P511 FRIEDBERR-1974-OPT-COMMUN-V10-P298 FRIEDBERR-1974-PHYS-REV-A-V10-P1728 GENDENSHTEIN LE-1985-USP-FIZ-NAUK+-V146-P553 GERRY CC-1989-PHYS-REV-A-V39-P971 GERRY CC-1988-PHYS-REV-A-V37-P1779 GLAUBER RJ-1963-PHYS-REV-V131-P2766 GLAUBER RJ-1963-PHYS-REV-V130-P2529 GOROKHOV AV-1988-MATEMATICHESKIE-PROB-P139 HAKEN H-1983-ADV-SYNERGETICS HALL RL-1983-J-MATH-PHYS-V24-P324 HALL RL-1992-J-PHYS-A-MATH-GEN-V25-P4459 HALL RL-1985-PHYS-REV-A-V32-P14 HILLERY M-1987-OPT-COMMUN-V62-P135 HILLERY M-1984-PHYS-REV-A-V29-P1275 HILLERY M-1982-PHYS-REV-A-V26-P451 INOMATA A-1992-PATH-INTEGRALS-COHER JAYNES ET-1963-P-IEEE-V51-P89 KIBLER M-1993-INT-J-QUANTUM-CHEM-V45-P209 KIBLER M-1987-PHYS-LETT-A-V121-P42 KISELEV JF-1988-MOD-PHYS-LETT-B-V1-P409 KISELEV YF-1988-ZH-EKSP-TEOR-FIZ+-V94-P344 KLEINERT H-1993-PHYS-LETT-B-V300-P261 KOCHAROVSKAYA OA-1988-JETP-LETT+-V48-P581 KOCHAROVSKAYA OA-1991-OPT-COMMUN-V84-P393 KOCHETOV EA-1992-J-PHYS-A-MATH-GEN-V25-P411 KOCHETOV EA-1993-JINR-E1793122-PREPR KOSHETOV EA-1992-LASER-PHYS-V2-P770 LONDON R-1987-J-MOD-OPTICS-V34-P709 MELEZHIK VS-1993-JINR-E49394-PREPR MUR VD-1992-J-MOSC-PHYS-SOC-V2-P189 OHNUKI Y-1978-PROG-THEOR-PHYS-V60-P548 PARADOPOULOS GJ-1986-J-MATH-PHYS-V27-P221 PERELOMOV AM-1987-OBOBSHCHENNYE-KOGERE POPOV VS-1993-PHYS-LETT-A-V172-P193 RUDAVETS AG-1993-LASER-PHYS-V3-P522 SANDERS J-1985-AVERAGING-METHODS-NO SCHRODINGER E-1926-NATURWISSENSCHAFTEN-V14-P664 SIMON B-1991-B-AM-MATH-SOC-V24-P303 STEVENSON PM-1981-PHYS-REV-D-V24-P1622 STEVENSON PM-1981-PHYS-REV-D-V23-P2916 SUKHATME U-1983-PHYS-REV-D-V28-P418 TANAS R-1984-COHERENCE-QUANTUM-OP-P643 VANKAMPEN NG-1985-PHYS-REP-V124-P69 WENIGER EJ-1993-J-MATH-PHYS-V34-P571 WENIGER EJ-1992-NUMERICAL-ALGORITHMS-V3-P477 WODKIEWICZ K-1985-J-OPT-SOC-AM-B-V2-P458 YUKALOV VI-1980-ANN-PHYS-LEIPZIG-V37-P171 YUKALOV VI-1979-ANN-PHYS-LEIPZIG-V36-P31 YUKALOV VI-1989-INT-J-MOD-PHYS-B-V3-P1691 YUKALOV VI-1992-J-MATH-PHYS-V33-P3994 YUKALOV VI-1991-J-MATH-PHYS-V32-P1235 YUKALOV VI-1990-J-MOD-OPTIC-V37-P1361 YUKALOV VI-1990-K-FIZICHESKIM-OSNOVA-P28 YUKALOV VI-1993-LASER-PHYS-V3-P870 YUKALOV VI-1992-LASER-PHYS-V2-P559 YUKALOV VI-1991-LASER-PHYS-V1-P85 YUKALOV VI-1990-PHYSICA-A-V167-P833 YUKALOV VI-1976-TEOR-MAT-FIZ-V28-P92 YUKALOV VI-1976-VESTN-MOSK-U-FIZ-AS+-V17-P270 YUKALOVA EP-1993-J-PHYS-A-MATH-GEN-V26-P2011 YUKALOVA EP-1993-PHYS-LETT-A-V175-P27 YUKALOVA EP-1993-PHYS-SCR-V7-P610
Source item page count:	16
Publication Date:	AUG
IDS No.:	PM837
29-char source abbrev:	IZV AKAD NAUK FIZ

Record 39 of 74
Author(s):	DUNN M; GERMANN TC; GOODSON DZ; TRAYNOR CA; MORGAN JD; WATSON DK; HERSCHBACH DR
Title:	A LINEAR ALGEBRAIC-METHOD FOR EXACT COMPUTATION OF THE COEFFICIENTS OF THE 1/D EXPANSION OF THE SCHRODINGER-EQUATION
Source:	JOURNAL OF CHEMICAL PHYSICS 1994, Vol 101, Iss 7, pp 5987-6004
No. cited references:	45
Addresses:	DUNN M, UNIV OKLAHOMA, DEPT PHYS & ASTRON, NORMAN, OK 73019. HARVARD UNIV, DEPT CHEM, CAMBRIDGE, MA 02138. SO METHODIST UNIV, DEPT CHEM, DALLAS, TX 75275. UNIV DELAWARE, DEPT PHYS & ASTRON, NEWARK, DE 19716. HARVARD SMITHSONIAN CTR ASTROPHYS, INST THEORET ATOM & MOLEC PHYS, CAMBRIDGE, MA 02138.
KeywordsPlus:	DIMENSIONAL PERTURBATION-THEORY; 2-ELECTRON ATOMS; VARIABLE DIMENSIONALITY; QUANTUM-MECHANICS; EXCITED-STATES; STRONG-FIELD; LIMIT; INTERPOLATION; ENERGIES; SYSTEMS
Abstract:	The 1/D expansion, where D is the dimensionality of space, offers a promising new approach for obtaining highly accurate solutions to the Schrodinger equation for atoms and molecules. The method typically employs an asymptotic expansion calculated to rather large order. Computation of the expansion coefficients has been feasible for very small systems, but extending the existing computational techniques to systems with more than three degrees of freedom has proved difficult. We present a new algorithm that greatly facilitates this computation. It yields exact values for expansion coefficients, with less roundoff error than the best alternative method. Our algorithm is formulated completely in terms of tenser arithmetic, which makes it easier to extend to systems with more than three degrees of freedom and to excited stares, simplifies the development of computer codes, simplifies memory management, and makes it well suited for implementation on parallel computer architectures. We formulate the algorithm for the calculation of energy eigenvalues, wave functions, and expectation values for an arbitrary many-body system and give estimates of storage and computational costs.
Cited references:	ADER JP-1983-PHYS-LETT-A-V97-P178 AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BAKER JD-1990-PHYS-REV-A-V41-P1247 BENDER CM-1978-ADV-MATH-METHODS-SCI BENDER CM-1982-PHYS-REV-A-V25-P1305 DUNN M-1993-DIMENSIONAL-SCALING-P375 DUNN M-UNPUB-J-PHYS-A FRANTZ DD-1988-CHEM-PHYS-V126-P59 GERMANN TC-IN-PRESS-COMPUT-PHYS GERMANN TC-1993-J-CHEM-PHYS-V99-P7739 GERMANN TC-UNPUB-PHYS-REV-LETT GOODSON DZ-1993-DIMENSIONAL-SCALING-P275 GOODSON DZ-1993-DIMENSIONAL-SCALING-P359 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1993-PHYS-REV-A-V48-P2668 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 HILL RN-1985-J-CHEM-PHYS-V83-P1173 HYLLERAAS EA-1930-Z-PHYSIK-V65-P209 KAIS S-1993-J-CHEM-PHYS-V98-P3990 KNIGHT RE-1963-REV-MOD-PHYS-V35-P436 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOPEZCABRERA M-1993-J-PHYS-CHEM-US-V97-P2467 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MATTHEWS J-1970-MATH-METHODS-PHYSICS-P366 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MORGAN JD-1993-DIMENSIONAL-SCALING-P336 POPOV VS-1993-PHYS-LETT-A-V172-P193 POPOV VS-1987-PHYS-LETT-A-V124-P77 ROST JM-1993-J-PHYS-CHEM-US-V97-P2461 ROTENBERG M-1970-ADVANCES-ATOMIC-MOLE-V6-P233 SLATER JC-1960-QUANTUM-THEORY-ELECT-V1 TAN AL-1993-DIMENSIONAL-SCALING-P20 TRAYNOR CA-1993-J-PHYS-CHEM-US-V97-P2464 VAINBERG VM-1986-JETP-LETT+-V44-P9 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470 VAINBERG VM-1988-THEOR-MATH-PHYS+-V74-P269 VANVLECK JH-1973-WAVE-MECHANICS-1ST-5-P26 WILSON EB-1980-MOL-VIBRATIONS-P309 WITTEN E-1980-PHYS-TODAY-V33-P38 WITTEN E-1980-RECENT-DEV-GAUGE-THE-V59
Source item page count:	18
Publication Date:	OCT 1
IDS No.:	PH987
29-char source abbrev:	J CHEM PHYS

Record 40 of 74
Author(s):	POPOV VS; MUR VD
Title:	PERTURBATION-THEORY FOR QUASI-STATIONARY LEVELS
Source:	JETP LETTERS 1994, Vol 60, Iss 1, pp 66-70
No. cited references:	13
Addresses:	POPOV VS, INST THEORET & EXPTL PHYS, 117259 MOSCOW, RUSSIA. INT PHYS INST, 125040 MOSCOW, RUSSIA. MOSCOW STATE ENGN PHYS INST, 115409 MOSCOW, RUSSIA.
KeywordsPlus:	QUANTIZATION RULES; STATES
Abstract:	A perturbation-theory formula is derived for the energies of quasistationary states (resonances) in the semiclassical approximation. This formula is valid for resonances either below or above the barrier. It is illustrated for several potentials, for which a comparison can be made with exact solutions.
Cited references:	ALVAREZ G-1988-PHYS-REV-A-V37-P4079 BAZ AI-1946-EIGENFUNCTION-EXPANS CONNOR JNL-1973-MOL-PHYS-V25-P1469 KAPUR PL-1938-P-ROY-SOC-A-V166-P277 MUR VD-1993-JETP-LETT+-V57-P418 MUR VD-1990-JETP-LETT+-V51-P563 MUR VD-1993-SOV-PHYS-JETP-V77-P18 PERELOMOV AM-1966-ZH-EKSP-TEOR-FIZ+-V23-P924 POPOV VS-1991-PHYS-LETT-A-V157-P185 POPOV VS-1991-SOV-PHYS-JETP-V73-P9 POPOV VS-1967-SOV-PHYS-JETP-V26-P222 ZELDOVICH YB-1960-SOV-PHYS-JETP-V12-P542 ZELDOVICH YB-1972-SOV-PHYS-USP-V14-P673
Source item page count:	5
Publication Date:	JUL 10
IDS No.:	PD159
29-char source abbrev:	JETP LETT-ENGL TR

Record 41 of 74
Author(s):	KARLSSON HO; GOSCINSKI O
Title:	A DIRECT RECURSIVE RESIDUE GENERATION METHOD - APPLICATION TO PHOTOIONIZATION OF HYDROGEN IN STATIC ELECTRIC-FIELDS
Source:	JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS 1994, Vol 27, Iss 6, pp 1061-1072
No. cited references:	41
Addresses:	KARLSSON HO, UNIV UPPSALA, DEPT QUANTUM CHEM, BOX 518, S-75120 UPPSALA, SWEDEN.
KeywordsPlus:	STARK-INDUCED RESONANCES; ATOMIC-HYDROGEN; CI CALCULATIONS; SPECTROSCOPY; LIMIT
Abstract:	In studies of hydrogenic systems via the recursive residue generation method (RRGM) the major bottleneck is the matrix vector product HC, between the Hamiltonian matrix H and a Lanczos vector C. For highly excited states and/or strong perturbations the size of H grows fast leading to storage problems. By making-use of direct methods, i.e. avoidance of explicit construction on of large Hamiltonian matrices, such problems can be overcome. Utilizing the underlying analytical properties of the Laguerre basis e(-lambdar)L(k)2I+2(2lambdar) a direct RRGM (D-RRGM) for the unperturbed hydrogenic Hamiltonian is derived, changing the storage needs from scaling as N2 to 4N where N is the number of radial functions for each factorized H-0(l, m) block with the possibility of parallel processing. A further computational simplification is introduced by putting the expression for the photoionization (PI) cross section in the rational form conventionally used in the representation of density or states (DOS). This allows the construction of the PI cross section directly from the tridiagonal Lanczos matrix avoiding the explicit calculation of individual eigenvalues and eigenvectors. To illustrate and verify the method the PI cross section for a hydrogen atom in a static electric field, for both pi and cr polarization, was calculated for an electric field strength of F = 5714 V cm-1. Sufficiently large basis sets could be employed so that good comparison with experiment and other theoretical work was obtained, including the field-induced modulations near the zero-field ionization limit.
Cited references:	ALIJAH A-1992-J-PHYS-B-AT-MOL-OPT-V25-P5043 ALVAREZ G-1991-PHYS-REV-A-V44-P3062 BENDAZZOLI-1993-INT-J-QUANTUM-CHEM-V27-P287 BENDAZZOLI GL-1991-CHEM-PHYS-LETT-V185-P125 BRANDAS E-1989-RESONANCES CLARK CW-1982-J-PHYS-B-AT-MOL-OPT-V15-P1175 CULLUM JK-1985-LANCZOS-ALGORITHMS-L-V1 DELANDE D-1991-PHYS-REV-LETT-V66-P141 DELSART C-1987-J-PHYS-B-AT-MOL-OPT-V20-P4699 ERDELYI A-1953-HIGHER-TRANSCENDENTA-V2 FANO U-1968-REV-MOD-PHYS-V40-P441 FRIESNER RA-1987-INT-J-SUPERCOMPUT-AP-V1-P9 GLAB WL-1985-PHYS-REV-A-V31-P530 GLAB WL-1985-PHYS-REV-A-V31-P3677 GOLDMAN SP-1989-PHYS-REV-A-V40-P1185 HARMIN DA-1990-ATOMS-STRONG-FIELDS-P61 HARRISON R-1993-THEOR-CHIM-ACTA-V4-P255 HAYDOCK R-1980-SOLID-STATE-PHYSICS-V35-P216 HEINE V-1980-SOLID-STATE-PHYSICS-V35-P1 HERBST IW-1979-COMMUN-MATH-PHYS-V64-P279 HERBST IW-1978-PHYS-REV-LETT-V41-P67 KARLSSON HO-1992-J-PHYS-B-AT-MOL-OPT-V25-P5015 KNOWLES PJ-1984-CHEM-PHYS-LETT-V111-P315 LANCZOS C-1950-J-RES-NAT-BUR-STAN-B-V45-P255 NESBET RK-1967-PHYS-REV-V155-P51 NICOLAIDES CA-1990-P-NATO-ADV-STUDY-I OLSEN J-1990-CHEM-PHYS-LETT-V169-P463 PALDUS J-1976-THEORETICAL-CHEM-ADV-V2 POPOV VS-1990-PHYS-LETT-A-V149-P418 REINHARDT WP-1982-ANNU-REV-PHYS-CHEM-V33-P223 RESCIGNO TN-1975-PHYS-REV-A-V12-P522 ROOS B-1972-CHEM-PHYS-LETT-V15-P153 ROOS BO-1987-ADV-CHEM-PHYS-2-V69-P399 ROTENBERG M-1962-ANNALS-OF-PHYSICS-V19-P262 ROTTKE H-1986-PHYS-REV-A-V33-P301 SARGENT AL-1993-SIAM-NEWS-V26-P14 SCHNEIDER DJ-1989-ADV-CHEM-PHYS-V73-P387 SHAVITT I-1978-INT-J-QUANTUM-CHEM-S-V12-P5 SHAVITT I-1977-INT-J-QUANTUM-CHEM-S-V11-P131 SIEGBAHN PEM-1984-CHEM-PHYS-LETT-V109-P417 WYATT RE-1989-ADV-CHEM-PHYS-V73-P231
Source item page count:	12
Publication Date:	MAR 28
IDS No.:	ND749
29-char source abbrev:	J PHYS-B-AT MOL OPT PHYS

Record 42 of 74
Author(s):	ALLILUEV SP; POPOV VS
Title:	THEORY OF STARK-EFFECT - DIMENSIONAL SCALING EFFECT
Source:	ZHURNAL EKSPERIMENTALNOI I TEORETICHESKOI FIZIKI 1993, Vol 104, Iss 5, pp 3569-3578
No. cited references:	45
Addresses:	ALLILUEV SP, MOSCOW PHYS TECH INST, DOLGOPRUDNYI 111700, RUSSIA.
KeywordsPlus:	PERTURBATION-THEORY; QUANTUM-MECHANICS; HYDROGEN-ATOM; STRONG-FIELD; 1/N-EXPANSION
Cited references:	AHARONOV Y-1979-PHYS-REV-A-V20-P2245 AHARONOV Y-1979-PHYS-REV-LETT-V42-P1582 ALLILUEV SP-1982-DOKL-AKAD-NAUK-SSSR+-V265-P597 ALLILUEV SP-1979-PHYS-LETT-A-V73-P103 ALLILUEV SP-1957-ZH-EKSP-TEOR-FIZ-V33-P200 ALLILUEV SP-1982-ZH-EKSP-TEOR-FIZ+-V82-P77 BANDER M-1966-REV-MOD-PHYS-V38-P330 BANDER M-1966-REV-MOD-PHYS-V38-P346 BARGMANN V-1935-Z-PHYS-V99-P576 BARUT AO-1967-PHYS-REV-V160-P1149 BARUT AO-1967-PHYS-REV-V157-P1180 BARUT AO-1967-PHYS-REV-V156-P1538 BARUT AO-1967-PHYS-REV-V156-P1541 BENDER CM-1982-PHYS-REV-A-V25-P1305 CHATTERJEE A-1990-PHYS-REP-V186-P249 CISNEROS A-1969-J-MATH-PHYS-V10-P277 DERDI G-1965-ZH-EKSP-TEOR-FIZ-V48-P1445 DOLGOV AD-1979-PHYS-LETT-B-V86-P185 DOLGOV AD-1978-ZH-EKSP-TEOR-FIZ+-V75-P2010 EHRENFEST P-1917-P-AMSTERDAM-ACAD-V20-P200 FOCK V-1935-Z-PHYSIK-V98-P145 FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 FRONSDAL C-1967-PHYS-REV-V156-P1665 GORELIK GE-1983-RAZMERNOST-PROSTRANS-P197 HERSCHBACH DR-1983-DIMENSIONAL-SCALING KOHN W-1955-PHYS-REV-V98-P915 LOUDON R-1959-AM-J-PHYS-V27-P649 MUR VD-1990-ZH-EKSP-TEOR-FIZ-V97-P92 PERELOMOV AM-1968-ZH-EKSP-TEOR-FIZ-V54-P1799 PERELOMOV AM-1966-ZH-EKSP-TEOR-FIZ-V50-P179 POPOV VS-1983-DIMENSIONAL-SCALING-P179 POPOV VS-1967-FIZIKA-VYSOKIKH-ENER-P702 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 PRIVMAN V-1980-PHYS-REV-A-V22-P1833 RIORDAN D-1963-VVEDENIE-KOMBINATORN SCHWINGER J-1964-J-MATH-PHYS-V5-P1606 SILVERSTONE HJ-1978-PHYS-REV-A-V18-P1853 TURBINER AV-1984-USP-FIZ-NAUK+-V144-P35 VAINBERG VM-1990-ZH-EKSP-TEOR-FIZ+-V98-P847 VAINBERG VM-1981-ZH-EKSP-TEOR-FIZ+-V81-P1567 YAFFE LG-1983-PHYS-TODAY-V36-P50 YANG XL-1991-PHYS-REV-A-V43-P1186 ZASLOW B-1967-AM-J-PHYS-V35-P1118
Source item page count:	10
Publication Date:	NOV
IDS No.:	ML388
29-char source abbrev:	ZH EKSP TEOR FIZ

Record 43 of 74
Author(s):	GERMANN TC; KAIS S
Title:	LARGE-ORDER DIMENSIONAL PERTURBATION-THEORY FOR COMPLEX ENERGY EIGENVALUES
Source:	JOURNAL OF CHEMICAL PHYSICS 1993, Vol 99, Iss 10, pp 7739-7747
No. cited references:	36
Addresses:	GERMANN TC, HARVARD UNIV, DEPT CHEM, CAMBRIDGE, MA 02138.
KeywordsPlus:	SCHRODINGER-EQUATION; RESONANCE STATES; 2-ELECTRON ATOMS; STRONG-FIELD; 1/N-EXPANSION; LIMIT; INTERPOLATION; ROTATION
Abstract:	Dimensional pertubation theory is applied to the calculation of complex energies for quasibound, or resonant, eigenstates of central potentials. Energy coefficients for an asymptotic expansion in powers of 1/kappa, where kappa = D + 2l and D is the Cartesian dimensionality of space, are computed using an iterative matrix based procedure. For effective potentials which contain a minimum along the real axis in the kappa --> infinity limit, Hermite-Pade summation is employed to obtain complex eigenenergies from real expansion coefficients. For repulsive potentials, we simply allow the radial coordinate to become complex and obtain complex expansion coefficients. Results for ground and excited states are presented for squelched harmonic oscillator (V0r2e(-r) and Lennard-Jones (12-6) potentials. Bound and quasibound rovibrational states for the hydrogen molecule are calculated from an analytic potential. We also describe the calculation of resonances for the hydrogen atom Stark effect by using the separated equations in parabolic coordinates. The methods used here should be readily extendable to systems with multiple degrees of freedom.
Cited references:	ADER JP-1983-PHYS-LETT-A-V97-P178 BENDER CM-1978-ADV-MATH-METHODS-SCI CERJAN C-1978-INT-J-QUANTUM-CHEM-V14-P393 CHU SI-1980-J-CHEM-PHYS-V72-P4772 CONNOR JNL-1983-J-CHEM-PHYS-V78-P6161 DUNN M-UNPUB ENGDAHL E-1991-J-CHEM-PHYS-V94-P1636 FRIEDRICH H-1990-THEORETICAL-ATOMIC-P GERMANN TC-UNPUB GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERSCHBACH DR-1992-DIMENSIONAL-SCALING JUNKER BR-1982-ADV-ATOM-MOL-PHYS-V18-P207 KAIS S-1992-CHEM-PHYS-V161-P393 KAIS S-1993-J-CHEM-PHYS-V98-P3990 KAIS S-1991-J-CHEM-PHYS-V95-P9028 KOLOS W-1965-J-CHEM-PHYS-V43-P2429 KORSCH HJ-1982-J-PHYS-B-AT-MOL-OPT-V15-P1 LANDAU LD-1977-QUANTUM-MECHANICS LEVINE RD-1987-MOL-REACTION-DYNAMIC LOESER JG-1991-J-CHEM-PHYS-V95-P4525 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1985-J-PHYS-CHEM-US-V89-P3444 LOPEZCABRERA M-1993-J-PHYS-CHEM-US-V97-P2467 MANIV T-1987-J-CHEM-PHYS-V86-P1048 MAQUET A-1983-PHYS-REV-A-V27-P2946 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 PADE H-1892-ANN-ECOLE-NORMALE-V9-P1 PADE MH-1972-SIAM-J-NUMER-ANAL-V11-P447 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 PRESS WH-1992-NUMERICAL-RECIPES REINDHARDT WP-1982-MATH-FRONTIERS-COMPU-P41 WAECH TG-1967-J-CHEM-PHYSICS-V46-P4905
Source item page count:	9
Publication Date:	NOV 15
IDS No.:	MH744
29-char source abbrev:	J CHEM PHYS

Record 44 of 74
Author(s):	GOODSON DZ; WATSON DK
Title:	DIMENSIONAL PERTURBATION-THEORY FOR EXCITED-STATES OF 2-ELECTRON ATOMS
Source:	PHYSICAL REVIEW A 1993, Vol 48, Iss 4, pp 2668-2678
No. cited references:	35
Addresses:	GOODSON DZ, BROWN UNIV, DEPT CHEM, PROVIDENCE, RI 02912. UNIV OKLAHOMA, DEPT PHYS & ASTRON, NORMAN, OK 73019.
KeywordsPlus:	SCHRODINGER-EQUATION; ELECTRONIC-STRUCTURE; LIMIT; 1/N-EXPANSION; FIELD
Abstract:	Large-order dimensional perturbation theory, which yields high accuracy for ground-state energies, is applied here to excited states of the two-electron atom. Expansion coefficients are computed recursively using the moment method, which we formulate in terms of normal coordinates. We consider the first two excited S states of helium, corresponding, at the large-dimension limit, to one quantum in either the antisymmetric-stretch normal mode or the symmetric-stretch normal mode. Comparison with the hydrogenic limit has identified these states as Is 2s 3S and 1s2s 1S, respectively. We sum the 1/D expansions at D = 3, using summation procedures that take into account the dimensional singularity structure of the eigenvalues, and find convergence at D = 3 to the eigenvalues predicted by the hydrogenic assignments, despite apparent qualitative differences between the eigenfunctions at large D and those at D = 3. In the D --> infinity limit, the electrons are equidistant from the nucleus. Our results for 1s2s energies appear to imply that the shell structure is properly accounted for by terms in the expansion beyond the lowest order. This robustness of the 1/D expansion suggests that the method will be applicable to many-electron systems.
Cited references:	ADER JP-1983-PHYS-LETT-A-V97-P178 AVERY J-1991-INT-J-QUANTUM-CHEM-V39-P657 AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BENDER CM-1978-ADV-MATH-METHODS-SCI-P324 BENDER CM-1982-PHYS-REV-A-V25-P1305 DARBOUX MG-1878-J-MATH-V4-P377 DOMB C-1970-ADV-PHYS-V19-P339 DOREN DJ-1985-CHEM-PHYS-LETT-V118-P115 DOREN DJ-1987-J-CHEM-PHYS-V87-P433 DOREN DJ-1988-J-PHYS-CHEM-US-V92-P1816 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DUNN M-UNPUB GOODSON DZ-1993-DIMENSIONAL-SCALING-P275 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1992-PHYS-REV-A-V46-P5428 HERRICK DR-1983-ADV-CHEM-PHYS-V52-P1 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 KELLMAN ME-1980-PHYS-REV-A-V22-P1536 LEWIS GN-1916-J-AM-CHEM-SOC-V38-P762 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1986-J-CHEM-PHYS-V84-P3882 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MACEK J-1968-J-PHYSICS-B-V1-P831 NINHAM BW-1963-J-MATH-PHYS-V4-P679 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 TAN AL-1993-DIMENSIOAL-SCALING-C-P230 TRAYNOR CA-1993-J-PHYS-CHEM-US-V97-P2464 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470 WHITTAKER ET-1940-COURSE-MODERN-ANAL-P140 WILSON EB-1955-MOL-VIBRATIONS-P69 ZHEN Z-UNPUB
Source item page count:	11
Publication Date:	OCT
IDS No.:	MC717
29-char source abbrev:	PHYS REV A

Record 45 of 74
Author(s):	KUANG Y; GU JS
Title:	GENERALIZED WKB STUDIES OF SHAPE RESONANCE
Source:	JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS 1993, Vol 26, Iss 18, pp 3057-3061
No. cited references:	16
Addresses:	KUANG Y, CHENGDU UNIV SCI & TECHNOL, DEPT PHYS, SICHUAN 610065, PEOPLES R CHINA.
KeywordsPlus:	STATES; IONIZATION; THRESHOLD; IONS; XE
Abstract:	Based on the generalized WKB and complex energy method, we study the atomic shape resonance in the IPA model, where the photoionization cross section shows maximum structure at resonance energies near the top of the barrier, Only f states of atoms around Xe and Rn have observable shape resonance structures.
Cited references:	ALFARO V-1965-POTENTIAL-SCATTERING AMUSIA MY-1990-J-PHYS-B-AT-MOL-OPT-V23-P393 BECKER U-1986-PHYS-REV-A-V33-P841 CHENG KT-1983-PHYS-REV-A-V28-P2820 CONNOR JNL-1968-MOL-PHYS-V15-P37 HAENSEL R-1969-PHYS-REV-V188-P1375 HERMAN F-1963-ATOMIC-STRUCTURE-CAL KOLOSOV VV-1989-J-PHYS-B-AT-MOL-OPT-V22-P833 MANSON ST-1968-PHYS-REV-V165-P165 MILLER SC-1953-PHYS-REV-V91-P174 POPOV VS-1991-PHYS-LETT-A-V157-P185 QI D-1989-NUCL-INSTRUM-MTHODS-V280-P189 SHEPARD HK-1983-PHYS-REV-D-V27-P1288 TONG XM-1990-PHYS-REV-A-V42-P5348 YE K-1992-5TH-P-C-AT-MOL-PHYS YE K-1987-J-PHYSIQUE-V9-P527
Source item page count:	5
Publication Date:	SEP 28
IDS No.:	MA899
29-char source abbrev:	J PHYS-B-AT MOL OPT PHYS

Record 46 of 74
Author(s):	GLUSHKOV AV; IVANOV LN
Title:	DC STRONG-FIELD STARK-EFFECT - CONSISTENT QUANTUM-MECHANICAL APPROACH
Source:	JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS 1993, Vol 26, Iss 14, pp L379-L385
No. cited references:	27
Addresses:	GLUSHKOV AV, RUSSIAN ACAD SCI, INST SPECTR, TROITSK 142092, RUSSIA.
KeywordsPlus:	ATOMIC NUCLEUS COLLISIONS; POSITRON PAIR PRODUCTION; UNIFORM ELECTRIC-FIELD; HYDROGEN-ATOM; 1/N-EXPANSION; APPROXIMANTS; RESONANCES
Abstract:	The energies and the widths of the Stark resonances for the hydrogen atom are calculated using a new approach. It is based on the operator form of the perturbation theory of the Schrodinger equation. The method includes the physically reasonable distorted-waves approximation in the frame of the formally exact quantum-mechanical procedure. The zero-order Hamiltonian possessing only stationary states is determined only by its spectrum without specifying its explicit form. The method of calculation of the perturbation theory matrix elements is described.
Cited references:	BENASSI L-1980-J-PHYS-B-AT-MOL-OPT-V13-P911 DAMBURG RJ-1978-J-PHYS-B-AT-MOL-OPT-V11-P1921 DAMBURG RJ-1976-J-PHYS-B-AT-MOL-OPT-V9-P3149 FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 GLUSHKOV AV-1992-3RD-S-AT-SPECTR-MOSC GLUSHKOV AV-1992-ISAN-N921AS-PREPR HARMIN DA-1982-PHYS-REV-A-V26-P2656 HARMIN DA-1982-PHYS-REV-LETT-V49-P128 HEHENBERGER M-1975-PHYS-REV-A-V12-P1 IVANOV LN-1988-PHYS-REP-V164-P315 IVANOV LN-1991-PHYS-SCRIPTA-V43-P368 IVANOV LN-1991-PHYS-SCRIPTA-V43-P374 IVANOV LN-1975-QVANT-ELECTRON-V2-P585 IVANOVA EP-1985-PHYS-SCR-V32-P512 KOLOSOV VV-1987-J-PHYS-B-AT-MOL-OPT-V20-P2359 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P2011 KONDRATOVICH VD-1982-ZH-EKSP-TEOR-FIZ-V4-P1256 LANDAU LD-1964-QUANTUM-MECHANICS LISITSA VS-1987-USP-FYZ-NAUK-V153-P369 MAQUET A-1983-PHYS-REV-A-V27-P2946 NAYFEH MH-1984-ATOMIC-EXCITATION-RE POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1988-ZH-EKSP-TEOR-FIZ-V93-P450 SAKIMOTO K-1986-J-PHYS-B-AT-MOL-OPT-V19-P3011 STEBBINGS RF-1983-RYDBERG-STATES-ATOMS TELNOV DA-1989-J-PHYS-B-AT-MOL-OPT-V22-PL399
Source item page count:	7
Publication Date:	JUL 28
IDS No.:	LR830
29-char source abbrev:	J PHYS-B-AT MOL OPT PHYS

Record 47 of 74
Author(s):	MUR VD; POPOV VS
Title:	WKB METHOD FOR RESONANCES
Source:	ZHURNAL EKSPERIMENTALNOI I TEORETICHESKOI FIZIKI 1993, Vol 104, Iss 1, pp 2293-2313
No. cited references:	31
Addresses:	MOSCOW THEORET & EXPTL PHYS INST, MOSCOW, RUSSIA.
KeywordsPlus:	ORDER; APPROXIMATION; STATES; ATOMS
Abstract:	For the potentials with a barrier the analytical continuation of the Bohr - Sommerfeld quantization rule into the region of overbarrier resonances is derived. The equations obtained are valid for an arbitrary analytical potential satisfying the quasiclassical conditions and determine both the position of resonance E(r) and its width GAMMA. The results are demonstrated for a number of model potentials and also for the Stark effect in a strong field. The energy asymptotic of resonances in the strong coupling regime is found.
Cited references:	ADHIKARI R-1988-PHYS-REV-A-V38-P1679 ALVAREZ G-1988-PHYS-REV-A-V37-P4079 BATEMAN H-1953-HIGHER-TRANSCENDENTA-V1-PCH2 BEKENSTEIN JD-1969-PHYS-REV-V188-P130 BENDER CM-1977-PHYS-REV-D-V16-P1740 CASE KM-1950-PHYS-REV-V80-P797 CONNOR JNL-1973-MOL-PHYS-V25-P1469 DUNHAM JL-1932-PHYS-REV-V41-P713 FREMAN N-1967-VKB-PRIBLIZHENIE FROMAN N-1977-J-MATH-PHYS-V18-P96 KADOMTSEV MB-1981-ZH-EKSP-TEOR-FIZ-V380-P1715 KARNAKOV BM-1992-KVAZIKLASSICHESKOE-P KESARWANI RN-1980-J-MATH-PHYS-V21-P2852 KHEDING D-1965-VVEDENIE-METOD-FAZOV LANDAU LD-1974-KVANTOVAYA-MEKHANIKA MARINOV MS-1975-J-PHYS-A-MATH-GEN-V8-P1575 MARINOV MS-1974-ZH-EKSP-TEOR-FIZ+-V67-P1250 MIGDAL AB-1975-KACHESTVENNYE-METODY MUR VD-1990-JETP-LETT+-V51-P499 MUR VD-1988-JETP-LETT+-V48-P67 MUR VD-1993-PISMA-ESKP-TEOR-FIZ-V57-P406 NG K-1987-PHYS-REV-A-V35-P2508 POKROVSKII VL-1961-ZH-EKSP-TEOR-FIZ-V40-P1713 POPOV VS-1987-ITEP177-PREPR POPOV VS-1991-J-MOSCOW-PHYS-SOC-V1-P15 POPOV VS-1991-PHYS-LETT-A-V157-P185 POPOV VS-1990-PHYS-LETT-A-V149-P425 ROSENZWEIG C-1968-J-MATH-PHYS-V9-P849 SIMON B-1970-ANN-PHYS-V58-P76 VAINBERG VM-1987-ZH-EKSP-TEOR-FIZ-V93-P450 YARIS R-1978-PHYS-REV-A-V18-P1816
Source item page count:	21
Publication Date:	JUL
IDS No.:	LT621
29-char source abbrev:	ZH EKSP TEOR FIZ

Record 48 of 74
Author(s):	MUR VD; POPOV VS
Title:	QUANTIZATION RULES FOR ABOVE-BARRIER RESONANCES
Source:	JETP LETTERS 1993, Vol 57, Iss 7, pp 418-422
No. cited references:	9
Addresses:	MUR VD, MOSCOW ENGN PHYS INST, MOSCOW 115409, RUSSIA. RUSSIAN ACAD SCI, INST THEORET & EXPTL PHYS, MOSCOW 117259, RUSSIA.
KeywordsPlus:	APPROXIMATION; 1/N-EXPANSION
Abstract:	The Bohr-Sommerfeld quantization condition is analytically continued into the above-barrier region. The result is used to find the asymptotic behavior of the energies of resonances under strong-coupling conditions.
Cited references:	ALVAREZ G-1988-PHYS-REV-A-V37-P4079 BENDER CM-1977-PHYS-REV-D-V16-P1740 KESARWANI RN-1980-J-MATH-PHYS-V21-P90 LANDAU LD-1977-QUANTUM-MECHANICS NG K-1987-PHYS-REV-A-V35-P2508 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 VAINBERG VM-1987-JETP-LETT+-V46-P225 VAINBERG VM-1987-ZH-EKSP-TEOR-FIZ+-V66-P258
Source item page count:	5
Publication Date:	APR 10
IDS No.:	LG880
29-char source abbrev:	JETP LETT-ENGL TR

Record 49 of 74
Author(s):	KAIS S; HERSCHBACH DR
Title:	DIMENSIONAL SCALING FOR QUASI-STATIONARY STATES
Source:	JOURNAL OF CHEMICAL PHYSICS 1993, Vol 98, Iss 5, pp 3990-3998
No. cited references:	37
Addresses:	KAIS S, HARVARD UNIV, DEPT CHEM, CAMBRIDGE, MA 02138.
KeywordsPlus:	PERTURBATION-THEORY; CLASSICAL MECHANICS; RESONANCES; POTENTIALS; WIDTHS
Abstract:	Complex energy eigenvalues which specify the location and width of quasibound or resonant states are computed to good approximation by a simple dimensional scaling method. As applied to bound states, the method involves minimizing an effective potential function in appropriately scaled coordinates to obtain exact energies in the D --> infinity limit, then computing approximate results for D = 3 by a perturbation expansion in I/D about this limit. For resonant states, the same procedure is used, with the radial coordinate now allowed to be complex. Five examples are treated: the repulsive exponential potential (e(-r)); a squelched harmonic oscillator (r2e(-r)); the inverted Kratzer potential (r-1 repulsion plus r-2 attraction); the Lennard-Jones potential (r-12 repulsion, r-6 attraction); and quasibound states for the rotational spectrum of the hydrogen molecule (X 1SIGMA(g)+, v = 0, J = 0 to 50). Comparisons with numerical integrations and other methods show that the much simpler dimensional scaling method, carried to second-order (terms in 1/D2), yields good results over an extremely wide range of the ratio of level widths to spacings. Other methods have not yet evaluated the very broad H-2 rotational resonances reported here (J> 39), which lie far above the centrifugal barrier.
Cited references:	ALHASSID Y-1985-PHYS-REV-LETT-V54-P1746 ATABECK O-1982-J-PHYS-B-ATOM-MOL-PH-V19-P2689 AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BARDSLEY JN-1978-INT-J-QUANTUM-CHEM-V14-P343 BENJAMIN I-1986-PHYS-REV-A-V33-P2833 CHAN YM-1965-MOLEC-PHYS-V9-P349 CHATTERJEE A-1990-PHYS-REP-V186-P249 CHILD MS-1974-MOL-SPECTROSCOPY-V2-PCH7 CONNOR JNL-1983-J-CHEM-PHYS-V78-P6161 DOOLEN GD-1978-INT-J-QUANTUM-CHEM-V14-P523 FLUGGE S-1974-PRACTICAL-QUANTUM-ME-P178 GOODSON DZ-1992-J-CHEM-PHYS-V97-P8481 HERSCHBACH DR-1992-DIMENSIONAL-SCALING IMBO T-1984-PHYS-REV-D-V29-P1669 KAIS S-1992-CHEM-PHYS-V161-P161 KAIS S-1991-J-CHEM-PHYS-V95-P9028 KAIS S-1989-J-CHEM-PHYS-V91-P7791 KOLOS W-1965-J-CHEM-PHYS-V43-P2429 KORSCH HJ-1986-J-PHYS-B-AT-MOL-OPT-V19-P2139 LANDAU LD-1958-QUANTUM-MECHANICS-P440 LEROY RJ-1978-J-CHEM-PHYS-V69-P3622 LEROY RJ-1971-J-CHEM-PHYS-V54-P5114 LEROY RJ-1974-MOL-SPECTROSCOPY-V1-PCH3 LEVINE RD-1969-QUANTUM-MECHANICS-MO LOESER JG-1987-J-CHEM-PHYS-V86-P5635 MA ST-1946-PHYS-REV-V69-P668 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MUR VD-1990-SOV-PHYS-JETP-V70-P16 POPOV VS-1985-JETP-LETT+-V41-P539 POPOV VS-1991-PHYS-LETT-A-V157-P185 POPOV VS-1990-PHYS-LETT-A-V149-P418 REINHARDT WP-1982-ANNU-REV-PHYS-CHEM-V33-P223 ROST JM-IN-PRESS-J-PHYS-CHEM STPANOV SS-1991-SOV-PHYS-JETP-V73-P227 TOENNIES JP-1974-J-CHEM-PHYS-V61-P2461 WAECH TG-1967-J-CHEM-PHYSICS-V46-P4905 YAFFE LG-1982-REV-MOD-PHYS-V54-P407
Source item page count:	9
Publication Date:	MAR 1
IDS No.:	KR111
29-char source abbrev:	J CHEM PHYS

Record 50 of 74
Author(s):	RADANTSEV VF
Title:	STATIONARY CHARACTER OF 2D STATES IN INVERSION AND ACCUMULATION LAYERS ON ZERO-GAP HGCDTE
Source:	SEMICONDUCTOR SCIENCE AND TECHNOLOGY 1993, Vol 8, Iss 3, pp 394-398
No. cited references:	21
Addresses:	RADANTSEV VF, URAL STATE UNIV, INST PHYS & APPL MATH, LENIN ST 51, EKATHERINBURG 620083, RUSSIA.
KeywordsPlus:	CHARGE LAYERS; SEMICONDUCTORS; SUBBANDS; SURFACE; HG1-XCDXTE
Abstract:	2DEG in inversion and accumulation layers on narrow-gap and gapless (epsilon(g) less-than-or-equal-to 0) Hg1-xCdxTe were investigated by using capacitance spectroscopy in magnetic fields. Although 2D states in investigated systems with epsilon(g) less-than-or-equal-to 0 are supposed to be resonant states, capacitance magneto-oscillations are distinctly resolved. Broadening of Landau levels does not differ significantly from that in HgCdTe with epsilon(g) > 0. The experimental subband parameters are in a very good agreement with theoretical calculations, which ignore the interband tunnelling. The stationary character of 2D states in Kane semiconductors may be understood in the framework of the conception developed for the description of the vacuum condensate of electrons near nuclei with supercritical charge. Even for epsilon(g) = 0 the effective quasi-relativistic potential provides a non-penetrating or a slightly penetrating barrier for 2D states. As a result more than 97 % of subband states are true stationary states or are well defined. If we take into account the spin polarization terms in the effective potential, all the states turn out to be true stationary states.
Cited references:	ANDO T-1985-J-PHYS-SOC-JPN-V54-P2676 BRENIG W-1984-Z-PHYS-B-CON-MAT-V54-P191 DERYABINA TI-1983-FIZ-TEKH-POLUPROV-V17-P2065 MIGDAL AB-1978-FERMIONS-BOSONS-STRO MIGDAL AB-1977-ZH-EKSP-TEOR-FIZ+-V72-P834 NACHEV I-1990-NUOVO-CIMENTO-D-V12-P1143 POPOV VS-1991-ZH-EKSP-TEOR-FIZ+-V100-P20 RADANTSEV VF-1988-SOV-PHYS-SEMICOND+-V22-P1136 RADANTSEV VF-1989-ZH-EKSP-TEOR-FIZ+-V96-P1793 RADANTSEV VF-1985-ZH-EKSP-TEOR-FIZ+-V61-P1234 SLINKMAN J-1989-PHYS-REV-B-V39-P1251 SOBKOWICZ P-1989-ACTA-PHYS-POL-A-V75-P29 SOBKOWICZ P-1990-SEMICOND-SCI-TECH-V5-P183 STEPNIEWSKI R-1984-J-PHYS-C-SOLID-STATE-V17-PL853 TAKADA Y-1982-LECTURE-NOTES-PHYSIC-V152-P101 WOLLRAB R-1989-SEMICOND-SCI-TECH-V4-P491 ZAVIALOV VV-1992-SOV-PHYS-SEMICOND-V26-P388 ZELDOVICH YB-1971-USP-FIZ-NAUK-V105-P403 ZIEGLER A-1989-EUROPHYS-LETT-V8-P543 ZIEGLER A-1988-SOLID-STATE-COMMUN-V65-P805 ZOLLNER JP-1988-PHYS-STATUS-SOLIDI-B-V148-P611
Source item page count:	5
Publication Date:	MAR
IDS No.:	KR620
29-char source abbrev:	SEMICOND SCI TECHNOL

Record 51 of 74
Author(s):	LOPEZCABRERA M; TAN AL; LOESER JG
Title:	SCALING AND INTERPOLATION FOR DIMENSIONALLY GENERALIZED ELECTRONIC-STRUCTURE
Source:	JOURNAL OF PHYSICAL CHEMISTRY 1993, Vol 97, Iss 10, pp 2467-2478
No. cited references:	47
Addresses:	OREGON STATE UNIV, DEPT CHEM, CORVALLIS, OR 97331. UNIV MICHIGAN, DEPT PHYS, ANN ARBOR, MI 48109.
KeywordsPlus:	INTRASHELL EXCITED-STATES; 2-ELECTRON ATOMS; PSEUDOMOLECULAR ATOMS; QUANTUM-MECHANICS; EXPANSION; ENERGIES; GEOMETRY; FIELD; LIMIT
Abstract:	Simple electronic structure problems generalized with respect to the spatial dimensionality D have two singular limits, D --> 1 and D --> infinity. Suitable scalings render the limiting solutions finite and reveal their complementary characters: D --> 1 gives point (delta function) interactions between particles, while D --> infinity yields point probability distributions between those particles. A single scaling that treats both limits simultaneously allows one to construct approximate D = 3 solutions by interpolation between the much simpler limits. In this paper we show how to construct and utilize such a uniform scaling. We construct the scaling, solve the limits, and interpolate to D = 3 for six model problems: Yukawa potential, hydrogen atom in a spherical cavity, H-2+, Hartree-Fock H-2, and Hartree-Fock two-electron atoms in weak magnetic and electric fields. The interpolated D = 3 energies and properties are typically accurate to within a few percent, except for cases where the D --> infinity limit gives multiple or unstable solutions. Extensions and improvements are also discussed.
Cited references:	ALBEVERIO S-1988-SOLVABLE-MODELS-QUAN BANYARD KE-1969-J-CHEM-PHYS-V51-P2680 BENDER CM-1982-PHYS-REV-A-V25-P1305 BERNASCONI J-1981-PHYSICS-ONE-DIMENSIO BETHE HA-1977-QUANTUM-MECHANICS-ON-P227 CHATTERJEE A-1990-PHYS-REP-V186-P249 COHEN HD-1965-J-CHEM-PHYSICS-V43-P3558 DAS G-1966-J-CHEM-PHYS-V44-P87 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DOREN DJ-1986-PHYS-REV-A-V34-P2665 FRAGA S-1968-MANY-ELECTRON-SYSTEM-PCH8 FRANTZ DD-1988-CHEM-PHYS-V126-P59 FROST AA-1956-J-CHEM-PHYS-V25-P1150 GOODRICH FC-1972-PRIMER-QUANTUM-CHEM-P161 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 HARRIS FE-1992-ALGEBRAIC-DIAGRAMMAT-P46 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 HULTHEN L-1951-REV-MODERN-PHYSICS-V23-P1 KAIS S-1992-CHEM-PHYS-V161-P393 KAIS S-1991-J-CHEM-PHYS-V95-P9028 KENDALL MG-1961-COURSE-GEOMETRY-DIME-P16 KOLOS W-1960-REV-MOD-PHYS-V32-P219 LAI CH-1987-J-MATH-PHYS-V28-P1801 LANGHOFF PW-1966-J-CHEM-PHYS-V44-P505 LIEB EH-1966-MATH-PHYSICS-ONE-DIM LIPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 LOESER JG-1993-DIMENSIONAL-SCALING-P389 LOESER JG-1991-J-CHEM-PHYS-V95-P4525 LOESER JG-1987-J-CHEM-PHYS-V86-P2114 LOESER JG-1987-J-CHEM-PHYS-V86-P3512 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1986-J-CHEM-PHYS-V84-P3893 LOPEZ M-1991-THESIS-U-MICHIGAN MORENO G-1984-J-PHYS-B-AT-MOL-OPT-V17-P21 NOGAMI Y-1976-AM-J-PHYS-V44-P886 SCHAAD JL-1970-J-CHEM-PHYS-V53-P851 SPANIER J-1987-ATLAS-FUNCTIONS-P231 SZABO A-1989-MODERN-QUANTUM-CHEM-P192 TAN AL-1993-DIMENSIOAL-SCALING-C-P230 TAN AL-1992-THESIS-HARVARD-U TENHOOR MJ-1968-INT-J-QUANTUM-CHEM-V2-P109 TOLDY LL-1976-AM-J-PHYS-V44-P1192 VAINBERG VM-1986-JETP-LETT+-V44-P9 VANVLECK JH-1932-THEORY-ELECTRIC-MAGN-P91 WIND H-1965-J-CHEM-PHYS-V42-P2371 ZHEN Z-1993-DIMENSIONAL-SCALING-P83
Source item page count:	12
Publication Date:	MAR 11
IDS No.:	KT155
29-char source abbrev:	J PHYS CHEM

Record 52 of 74
Author(s):	POPOV VS
Title:	ON THE THEORY OF THE ABOVE-THE-BARRIER STARK RESONANCES
Source:	PHYSICS LETTERS A 1993, Vol 173, Iss 1, pp 63-68
No. cited references:	23
Addresses:	POPOV VS, MOSCOW THEORET & EXPTL PHYS INST, MOSCOW 117259, RUSSIA.
KeywordsPlus:	HYDROGEN-ATOM; PERTURBATION-THEORY; QUANTUM-MECHANICS; ELECTRIC-FIELD; 1/N-EXPANSION; PHOTOIONIZATION
Abstract:	A semiclassical 1/n-expansion for the Stark effect in a strong electric field epsilon is considered, which gives simple analytic formulae determining the atomic widths GAMMA(n)(epsilon). It has been shown that there is a range in which the widths of the Stark resonances depend almost linearly on the applied electric field, which agrees with numerical calculations.
Cited references:	ALVAREZ G-1991-PHYS-REV-A-V44-P3060 BENASSI L-1979-PHYS-REV-LETT-V42-P704 BENASSI L-1979-PHYS-REV-LETT-V42-P1430 BENDER CM-1982-PHYS-REV-A-V25-P1305 CHATTERJEE A-1990-PHYS-REP-V186-P249 FRANCESCHINI V-1985-PHYS-REV-A-V32-P1338 GLAB WL-1985-PHYS-REV-A-V31-P3677 KOLOSOV VV-1986-PISMA-ZHETF-V44-P457 MUR VD-1988-JETP-LETT+-V48-P67 MUR VD-1990-ZH-EKSP-TEOR-FIZ+-V97-P32 MUR VD-1988-ZH-EKSP-TEOR-FIZ+-V94-P125 NG K-1987-PHYS-REV-A-V35-P2508 POPOV VS-1992-ITEP5892-PREPR POPOV VS-1985-JETP-LETT+-V41-P439 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 POPOV VS-1986-YAD-FIZ-V44-P1103 TELNOV DA-1989-J-PHYS-B-AT-MOL-OPT-V22-PL399 WEINBERG VM-1987-JETP-LETT+-V46-P178 WEINBERG VM-1986-PISMA-ZH-EKSP-TEOR-F-V44-P9 WEINBERG VM-1987-ZH-EKSP-TEOR-FIZ+-V93-P450 YAMABE T-1977-PHYS-REV-A-V16-P877
Source item page count:	6
Publication Date:	JAN 25
IDS No.:	KJ198
29-char source abbrev:	PHYS LETT A

Record 53 of 74
Author(s):	ALIJAH A
Title:	PHOTOIONIZATION OF ATOMIC-HYDROGEN IN ELECTRIC-FIELDS
Source:	JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS 1992, Vol 25, Iss 23, pp 5043-5053
No. cited references:	31
Addresses:	ALIJAH A, UNIV BIELEFELD, FAK CHEM, POSTFACH 100131, W-4800 BIELEFELD 1, GERMANY.
KeywordsPlus:	STARK-INDUCED RESONANCES; INTERFERENCE PHENOMENA; SHAPE RESONANCES; HIGH-ORDER; SPECTRUM; STATES; PHOTOIONISATION; SPECTROSCOPY; IONIZATION; DENSITY
Abstract:	Photoionization spectra of atomic hydrogen in a homogeneous electric field are calculated by exact integration of the Schrodinger equation for both negative and positive energies and compared with various experimental data. The numerical method allows the spectra to be decomposed into contributions from the parabolic substates labelled by the quantum number n1. On this basis the field-induced continuum oscillations are discussed.
Cited references:	ALIJAH A-1986-J-PHYS-B-AT-MOL-OPT-V19-P2617 ALVAREZ G-1991-PHYS-REV-A-V44-P3060 ALVAREZ G-1989-PHYS-REV-LETT-V63-P1364 BERGEMAN T-1984-PHYS-REV-LETT-V53-P775 BETHE HA-1957-QUANTUM-MECHANICS-ON DAMBURG RJ-1976-J-PHYS-B-AT-MOL-OPT-V9-P3149 DELSART C-1987-J-PHYS-B-AT-MOL-OPT-V20-P4699 GLAB WL-1985-PHYS-REV-A-V31-P530 GLAB WL-1985-PHYS-REV-A-V31-P3677 GRODZANOV TP-1988-PHYS-LETT-A-V132-P262 HARMIN DA-1985-PHYS-REV-A-V31-P2984 HARMIN DA-1982-PHYS-REV-A-V26-P2656 HARMIN DA-1981-PHYS-REV-A-V24-P2491 JOHNSON BR-1977-J-CHEM-PHYS-V67-P4086 KOLOSOV VV-1988-J-PHYS-B-ATOM-MOL-PH-V22-P833 KOLOSOV VV-1989-PHYS-LETT-A-V140-P36 KONDRATOVICH VD-1990-J-PHYS-B-AT-MOL-OPT-V23-P21 KONDRATOVICH VD-1990-J-PHYS-B-AT-MOL-OPT-V23-P3785 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P1981 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P2011 LANDAU LD-1979-LEHRBUCH-THEORETISCH-V3 LISITSA VS-1987-SOV-PHYS-USP-V30-P927 LUCKOENIG E-1980-J-PHYS-B-AT-MOL-OPT-V13-P1743 LUCKOENIG E-1980-J-PHYS-B-AT-MOL-OPT-V13-P1769 MILNE WE-1930-PHYS-REV-V35-P863 NICOLAIDES CA-1990-1988-P-NATO-ADV-STUD POPOV VS-1990-PHYS-LETT-A-V149-P425 ROTTKE H-1986-PHYS-REV-A-V33-P301 SILVERMAN JN-1988-CHEM-PHYS-LETT-V153-P61 SILVERSTONE HJ-1990-1988-P-NATO-ADV-STUD SILVERSTONE HJ-1978-PHYS-REV-A-V18-P1853
Source item page count:	11
Publication Date:	DEC 14
IDS No.:	KE313
29-char source abbrev:	J PHYS-B-AT MOL OPT PHYS

Record 54 of 74
Author(s):	GOODSON DZ; LOPEZCABRERA M; HERSCHBACH DR; MORGAN JD
Title:	LARGE-ORDER DIMENSIONAL PERTURBATION-THEORY FOR 2-ELECTRON ATOMS
Source:	JOURNAL OF CHEMICAL PHYSICS 1992, Vol 97, Iss 11, pp 8481-8496
No. cited references:	65
Addresses:	GOODSON DZ, HARVARD UNIV, DEPT CHEM, CAMBRIDGE, MA 02138. UNIV DELAWARE, DEPT PHYS & ASTRON, NEWARK, DE 19716. HARVARD SMITHSONIAN CTR ASTROPHYS, INST THEORET ATOM & MOLEC PHYS, CAMBRIDGE, MA 02138.
KeywordsPlus:	LARGE N-EXPANSION; SCHRODINGER-EQUATION; QUANTUM-MECHANICS; STRONG-FIELD; VARIABLE DIMENSIONALITY; ELECTRONIC-STRUCTURE; LIMIT; 1/N-EXPANSION; DEGENERACIES; SEPARATION
Abstract:	An asymptotic expansion for the electronic energy of two-electron atoms is developed in powers of delta=1/D, the reciprocal of the Cartesian dimensionality of space. The expansion coefficients are calculated to high order (approximately 20 to 30) by an efficient recursive procedure. Analysis of the coefficients elucidates the singularity structure in the D --> infinity limit, which exhibits aspects of both an essential singularity and a square-root branch point. Pade-Borel summation incorporating results of the singularity analysis yields highly accurate energies; the quality improves substantially with increase in either D or the nuclear charge Z. For He, we obtain 9 significant figures for the ground state and 11 for the 2p2 3P(e) doubly excited state, which is isomorphic with the ground state at D=5 by virtue of interdimensional degeneracy. The maximum accuracy obtainable appears to be limited only by accumulation of roundoff error in the expansion coefficients. The method invites application to systems with many electrons or subject to external fields.
Cited references:	ABRAMOVITZ A-1965-HDB-MATH-FUNCTIONS-P260 ADER JP-1983-PHYS-LETT-A-V97-P178 ARFKIN G-1985-MATH-METHODS-PHYSICI-P281 AVERY J-1991-INT-J-QUANTUM-CHEM-V39-P657 AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BAKER GA-1981-ENCY-MATH-ITS-APPLIC-V13-P48 BAKER JD-1990-PHYS-REV-A-V41-P1247 BENDER CM-1978-ADV-MATH-METHODS-SCI BENDER CM-1982-PHYS-REV-A-V25-P1305 CHATTERJEE A-1990-PHYS-REP-V186-P249 CHURCHILL RV-1984-COMPLEX-VARIABLES-AP-P126 DARBOUX MG-1878-J-MATH-V4-P377 DOMB C-1970-ADV-PHYS-V19-P339 DOREN DJ-1985-CHEM-PHYS-LETT-V118-P115 DOREN DJ-1987-J-CHEM-PHYS-V87-P433 DOREN DJ-1988-J-PHYS-CHEM-US-V92-P1816 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DUNHAM JL-1932-PHYS-REV-V41-P713 DUNHAM JL-1932-PHYS-REV-V41-P721 DUNN M-IN-PRESS FRANTZ DD-1988-CHEM-PHYS-V126-P59 GOODSON DZ-1992-IN-PRESS-PHYS-REV-A GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1991-PHYS-REV-A-V44-P97 GOODSON DZ-1991-PHYS-REV-A-V43-P4617 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 GOODSON DZ-UNPUB-PHYS-REV-A GOSCINSKI O-1986-INT-J-QUANTUM-CHEM-V29-P897 GRAFFI S-1970-PHYS-LETT-B-V32-P240 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1992-DIMENSIONAL-SCALING HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 LANGMUIR I-1919-J-AM-CHEMICAL-SOC-V41-P868 LEWIS GN-1916-J-AM-CHEM-SOC-V38-P762 LOESER JG-COMMUNICATION LOESER JG-1987-J-CHEM-PHYS-V86-P2114 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1986-J-CHEM-PHYS-V84-P3882 LOPEZCABRERA M-1992-PHYS-REV-LETT-V68-P1992 MIDTDAL J-1965-PHYS-REV-A-V138-P1010 MLODINOW LD-1981-ANN-PHYS-NEW-YORK-V131-P1 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MORGAN JD-1992-DIMENSIONAL-SCALING MUR VD-1990-SOV-PHYS-JETP-V70-P16 NINHAM BW-1963-J-MATH-PHYS-V4-P679 PADE H-1892-ANN-ECOLE-NORMALE-V9-P1 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1987-PHYS-LETT-A-V124-P77 ROSENTHAL CM-1971-J-CHEM-PHYS-V55-P2474 ROST JM-1992-PHYS-REV-A-V46-P2410 SHAFER RE-1974-SIAM-J-NUMER-ANAL-V11-P447 SOKAL AD-1980-J-MATH-PHYS-V21-P261 SUKHATME U-1983-PHYS-REV-D-V28-P418 TAN AL-1992-DIMENSIONAL-SCALING VAINBERG VM-1986-JETP-LETT+-V44-P9 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470 VANVLECK JH-1970-PURE-APPL-CHEM-V24-P235 WHITTAKER ET-1940-COURSE-MODERN-ANAL-P140 WILSON EB-1955-MOL-VIBRATIONS WITTEN E-1980-NATO-ADV-STUDY-I-S-B-V59 WITTEN E-1980-PHYS-TODAY-V33-P38 WONG R-1989-ASYMPTOTIC-APPROXIMA-P116
Source item page count:	16
Publication Date:	DEC 1
IDS No.:	KA706
29-char source abbrev:	J CHEM PHYS

Record 55 of 74
Author(s):	GAVRILOV VE; GAVRILOVA TV
Title:	ON THE OPTICAL-PROPERTIES OF A DENSE XENON PLASMA
Source:	OPTIKA I SPEKTROSKOPIYA 1991, Vol 71, Iss 5, pp 736-737
No. cited references:	11
Addresses:	GAVRILOV VE, SI VAVILOV STATE OPT INST, LENINGRAD, USSR.
KeywordsPlus:	PULSED-DISCHARGE PLASMA; SPECTRUM; TUBE
Cited references:	ANDREEV SI-1970-ZH-PRIKL-SPEKTROSK-V13-P988 ANDREEV SI-1971-ZHPS-V14-P310 BAKEEV AA-1969-RADIOTEKH-ELEKTRON+-V14-P1998 GAVRILOV VE-1986-OPT-SPEKTROSK+-V61-P1192 GAVRILOV VE-1985-OPT-SPEKTROSK+-V59-P426 GAVRILOV VE-1985-OPT-SPEKTROSK+-V59-P1012 GUNHTER K-1970-BEITR-PLASMASPHYSIK-V10-P469 GUNHTER K-1968-BEITR-PLASMASPHYSIK-V8-P383 KREPOSTNOV PI-1989-OPT-SPEKTROSK+-V67-P538 POPOVICH VE-1971-OPT-SPEKTROSK-V9-P627 VINOKUROV GN-1989-OPT-SPEKTROSK-V67-P452
Source item page count:	2
Publication Date:	NOV
IDS No.:	HM161
29-char source abbrev:	OPT SPEKTROSK

Record 56 of 74
Author(s):	LOPEZCABRERA M; GOODSON DZ; HERSCHBACH DR; MORGAN JD
Title:	LARGE-ORDER DIMENSIONAL PERTURBATION-THEORY FOR H2+
Source:	PHYSICAL REVIEW LETTERS 1992, Vol 68, Iss 13, pp 1992-1995
No. cited references:	38
Addresses:	LOPEZCABRERA M, HARVARD UNIV, DEPT CHEM, CAMBRIDGE, MA 02138. UNIV DELAWARE, DEPT PHYS & ASTRON, NEWARK, DE 19716.
KeywordsPlus:	LARGE N-EXPANSION; 2-ELECTRON ATOMS; VARIABLE DIMENSIONALITY; QUANTUM-MECHANICS; GROUND-STATE; LIMIT; ENERGY; H-2+; 1/N-EXPANSION; INTERPOLATION
Abstract:	An asymptotic expansion for the electronic energy of H-2(+) is developed in inverse powers of D, the spatial dimension, and the singularity structure in the D --> infinity limit is elucidated by analysis of the coefficients at large order (approximately 30 to 45). For the ground state and several excited states, Pade-Borel summation yields an accuracy of eight or more significant figures.
Cited references:	ADER JP-1983-PHYS-LETT-A-V97-P178 AVERY J-1991-THEOR-CHIM-ACTA-V81-P1 BENDER CM-1982-PHYS-REV-A-V25-P1305 BREZIN E-1979-J-PHYS-LETT-PARIS-V40-PL511 BROWN WB-1966-J-CHEM-PHYS-V44-P3934 CIZEK J-1986-PHYS-REV-A-V33-P12 DOREN DJ-1985-CHEM-PHYS-LETT-V118-P115 DOREN DJ-1987-J-CHEM-PHYS-V87-P433 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DOREN DJ-1986-PHYS-REV-A-V34-P2665 FRANTZ DD-1988-CHEM-PHYS-V126-P59 FRANTZ DD-1990-J-CHEM-PHYS-V92-P6668 FRANTZ DD-1989-PHYS-REV-A-V40-P1175 GOODSON DZ-IN-PRESS GOODSON DZ-IN-PRESS-DIMENSIONAL GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1628 GOSCINSKI O-1986-INT-J-QUANTUM-CHEM-V29-P897 GRAFFI S-1970-PHYS-LETT-B-V32-P240 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 LOESER JG-1991-J-CHEM-PHYS-V95-P4525 LOESER JG-1987-J-CHEM-PHYS-V86-P3512 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1985-J-PHYS-CHEM-US-V89-P3444 LOPEZCABRERA M-1991-THESIS-U-MICHIGAN-AN MLODINOW LD-1981-ANN-PHYS-NEW-YORK-V131-P1 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 MORGAN JD-1980-INT-J-QUANTUM-CHEM-V17-P1143 MUR VD-1990-SOV-PHYS-JETP-V70-P16 NINHAM BW-1963-J-MATH-PHYS-V4-P679 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 SHAFER RE-1974-SIAM-J-NUMER-ANAL-V11-P447 SOKAL AD-1980-J-MATH-PHYS-V21-P261 VAINBERG VM-1990-SOV-PHYS-JETP-V71-P470 WHITTAKER ET-1940-COURSE-MODERN-ANAL
Source item page count:	4
Publication Date:	MAR 30
IDS No.:	HL670
29-char source abbrev:	PHYS REV LETT

Record 57 of 74
Author(s):	PANJA MM; BAG M; DUTT R; VARSHNI YP
Title:	LARGE-N EXPANSION METHOD FOR A SPIN-1/2 PARTICLE IN THE PRESENCE OF VECTOR AND SCALAR POTENTIALS
Source:	PHYSICAL REVIEW A 1992, Vol 45, Iss 3, pp 1523-1530
No. cited references:	56
Addresses:	PANJA MM, VISVA BHARATI UNIV, DEPT PHYS, SANTINIKETAN 731235, W BENGAL, INDIA. UNIV OTTAWA, DEPT PHYS, OTTAWA K1N 6N5, ONTARIO, CANADA.
KeywordsPlus:	SHIFTED 1/N EXPANSION; RELATIVISTIC PERTURBATION-THEORY; SCREENED COULOMB POTENTIALS; DIRAC-EQUATION; ENERGY-LEVELS; SCHRODINGER-EQUATION; HYDROGEN-ATOM; CENTRAL FIELD; BOUND-STATES; MODEL
Abstract:	The shifted large-N technique (SLNT) has been applied to study the relativistic motion of a particle in the presence of vector and scalar interactions with special emphasis on the construction of both large- and small-component Dirac radial wave functions. Numerical results for the binding energy for a particle in the presence of the Coulomb plus linear confining potential compare very well with those obtained by the elaborate analytic approximation method using the Pade-approximation technique. We illustrate that one recovers not only the exact analytic results for binding energies for vector and scalar Coulomb potentials, but also exact wave functions from the leading-order SLNT calculation. This motivates future applications of the same method to more realistic atomic systems governed by screened Coulomb potentials where the knowledge of the large and small components of the radial wave function is essential.
Cited references:	ABRAMOWITZ M-1964-HDB-MATH-FUNCTIONS AHARONOV Y-1980-PHYS-REV-LETT-V44-PE619 AHARONOV Y-1979-PHYS-REV-LETT-V43-PE176 AHARONOV Y-1979-PHYS-REV-LETT-V42-P1582 ATAG S-1989-J-MATH-PHYS-V30-P696 AU CK-1980-PHYS-REV-A-V22-P1820 AU CK-1979-PHYS-REV-A-V20-P2245 BELL JS-UNPUB CEA P-1982-PHYS-REV-D-V26-P1157 CHATTERJEE A-1986-J-MATH-PHYS-V27-P2331 CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P735 CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P1193 CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P2403 CHATTERJEE A-1990-PHYS-REP-V186-P269 CRITCHFIELD CL-1976-J-MATH-PHYS-V17-P261 DAREWYCH JW-1971-PHYS-REV-A-V3-P502 DUTT R-1987-J-PHYS-B-AT-MOL-OPT-V20-P2437 DUTT R-1986-J-PHYS-B-AT-MOL-OPT-V19-P3411 DUTT R-1985-J-PHYS-B-AT-MOL-OPT-V18-P3311 DUTT R-1986-PHYS-REV-A-V34-P777 DUTT R-1986-Z-PHYS-D-ATOM-MOL-CL-V2-P207 FLUGGE S-1974-PRACTICAL-QUANTUM-ME FROMAN N-1981-J-PHYS-PARIS-V42-P1491 GOLDMAN T-1975-PHYS-REV-D-V12-P2910 GREEN AES-1969-PHYS-REV-V184-P1 GREEN AES-1971-PHYS-REV-A-V4-P1 GREINER W-1990-RELATIVISTIC-QUANTUM GUNION JF-1975-PHYS-REV-D-V12-P3583 IMBO T-1985-PHYS-REV-D-V31-P2655 IMBO T-1984-PHYS-REV-D-V29-P1669 KANG JS-1975-PHYS-REV-D-V12-P841 MAGYARI E-1980-PHYS-LETT-B-V95-P295 MALUENDES SA-1986-PHYS-REV-D-V34-P1835 MCENNAN J-1977-PHYS-REV-A-V16-P1768 MIKHAILOV AI-1968-SOV-PHYS-JETP-V27-P95 MIRAMONTES JL-1984-NUOVO-CIMENTO-B-V84-P10 MUSTAFA O-1991-PHYS-REV-A-V44-P4142 NIETO MM-1979-AM-J-PHYS-V47-P1067 PANJA MM-1990-PHYS-REV-A-V42-P106 PANJA MM-1988-PHYS-REV-A-V38-P3937 PAPP E-1991-PHYS-LETT-B-V259-P19 PAPP E-1991-PHYS-SCRIPTA-V43-P14 RAM B-1979-PHYS-REV-D-V19-P841 ROGERS GW-1984-PHYS-REV-A-V30-P35 ROSE ME-1961-RELATIVISTIC-ELECTRO ROY B-1990-J-PHYS-A-MATH-GEN-V23-P3555 ROYCHOUDHURY R-1989-PHYS-REV-A-V39-P5523 ROYCHOUDHURY RK-1987-J-PHYS-A-MATH-GEN-V20-PL1083 RUTKOWSKI A-1986-J-PHYS-B-AT-MOL-OPT-V19-P149 RUTKOWSKI A-1986-J-PHYS-B-AT-MOL-OPT-V19-P3431 SERGEEV AV-1984-SOV-J-NUCL-PHYS+-V39-P731 SOFF G-1973-Z-NATURFORSCH-A-V28-P1384 SU JY-1985-PHYS-REV-A-V32-P3251 SUKHATME U-1983-PHYS-REV-D-V28-P418 VRSCAY ER-1988-PHYS-LETT-A-V130-P141 WONG MKF-1990-J-MATH-PHYS-V31-P1677
Source item page count:	8
Publication Date:	FEB 1
IDS No.:	HC995
29-char source abbrev:	PHYS REV A

Record 58 of 74
Author(s):	ALVAREZ G; DAMBURG RJ; SILVERSTONE HJ
Title:	PHOTOIONIZATION OF ATOMIC-HYDROGEN IN AN ELECTRIC-FIELD
Source:	PHYSICAL REVIEW A 1991, Vol 44, Iss 5, pp 3060-3082
No. cited references:	48
Addresses:	ALVAREZ G, UNIV COMPLUTENSE MADRID, DEPT FIS TEOR, E-28040 MADRID, SPAIN. ACAD SCI LASSR, INST PHYS, RIGA 226006, LATVIA, USSR. JOHNS HOPKINS UNIV, DEPT CHEM, BALTIMORE, MD 21218.
KeywordsPlus:	PHOTOABSORPTION CROSS-SECTIONS; STARK-INDUCED RESONANCES; INTERFERENCE PHENOMENA; PERTURBATION-THEORY; SHAPE RESONANCES; RYDBERG ATOMS; IONIZATION; SPECTRUM; STATES; 1/N-EXPANSION
Abstract:	The photoionization cross section of atomic hydrogen in an electric field can be understood as the sum of resonance contributions. Each contribution is proportional to the imaginary part of the square of a complex transition-dipole matrix element divided by an energy denominator and has a naturally asymmetric line shape. The main features of experiments, including asymmetry of the lines, blue shift of maxima with respect to calculated resonances near zero energy, "field-induced" structure above zero energy, and increasing "background" that begins above the classical saddle-point energy, are reproduced via variational calculations of the resonance energies and wave functions in parabolic coordinates.
Cited references:	ABRAMOWITZ M-1964-NBS-APPLIED-MATH-SER-V55 ALIJAH A-1986-J-PHYS-B-AT-MOL-OPT-V19-P2617 ALVAREZ G-1989-PHYS-REV-A-V40-P3690 ALVAREZ G-1989-PHYS-REV-LETT-V63-P1364 BENASSI L-1980-J-PHYS-B-AT-MOL-OPT-V13-P911 BERGEMAN T-1984-PHYS-REV-LETT-V53-P775 COHEN ER-1989-PHYS-TODAY-V42-PBG8 DAMBURG RJ-1976-J-PHYS-B-AT-MOL-OPT-V9-P3149 DELANDE D-1991-PHYS-REV-LETT-V66-P141 FANO U-1961-PHYS-REV-V124-P1866 GLAB WL-1985-PHYS-REV-A-V31-P530 GLAB WL-1985-PHYS-REV-A-V31-P3677 GOLUB GH-1989-MATRIX-COMPUTATIONS-P359 GRAFFI S-1978-COMMUN-MATH-PHYS-V62-P83 HARMIN DA-1985-PHYS-REV-A-V31-P2984 HARMIN DA-1981-PHYS-REV-A-V24-P2491 HERBST IW-1979-COMMUN-MATH-PHYS-V64-P279 HUMBLET J-1952-MEM-SOC-ROY-SCI-LIEG-V12-P7 HUMBLET J-1961-NUCL-PHYS-V26-P529 ITZYKSON C-1980-QUANTUM-FIELD-THEORY JOHNSON WR-1985-ATOM-DATA-NUCL-DATA-V33-P405 KOLOSOV VV-1989-J-PHYS-B-AT-MOL-OPT-V22-P833 KOLOSOV VV-1987-J-PHYS-B-AT-MOL-OPT-V20-P2359 KONDRATOVICH VD-1990-J-PHYS-B-AT-MOL-OPT-V23-P21 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P1981 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P2011 LUCKOENIG E-1980-J-PHYS-B-AT-MOL-OPT-V13-P1743 LUCKOENIG E-1980-J-PHYS-B-AT-MOL-OPT-V13-P1769 LUDERS G-1951-ANN-PHYS-V8-P301 MAQUET A-1983-PHYS-REV-A-V27-P2946 MUR VD-1988-JETP-LETT+-V48-P70 MUR VD-1988-ZH-EKSP-TEOR-FIZ+-V67-P2027 NG K-1987-PHYS-REV-A-V35-P2508 NICOLAIDES CA-1990-NATO-ADV-STUDY-I-S-B-V212 POLIK WF-1988-J-CHEM-PHYS-V89-P3584 POPOV VS-1990-PHYS-LETT-A-V149-P418 POPOV VS-1990-PHYS-LETT-A-V149-P425 POPOV VS-1987-PHYS-LETT-A-V124-P77 RESCIGNO TN-1976-J-CHEM-PHYS-V64-P477 RESCIGNO TN-1975-PHYS-REV-A-V12-P522 ROTTKE H-1986-PHYS-REV-A-V33-P301 SCHRODINGER E-1926-ANN-PHYSIK-V80-P437 SILVERSTONE HJ-1990-NATO-ADV-STUDY-I-S-B-P295 SILVERSTONE HJ-1978-PHYS-REV-A-V18-P1853 SIMON B-1970-ANN-PHYS-V58-P76 TELNOV DA-1989-J-PHYS-B-AT-MOL-OPT-V22-PL399 VAINBERG VM-1986-JETP-LETT+-V44-P9 YAMABE T-1977-PHYS-REV-A-V16-P877
Source item page count:	23
Publication Date:	SEP 1
IDS No.:	GE936
29-char source abbrev:	PHYS REV A

Record 59 of 74
Author(s):	GOODSON DZ; MORGAN JD; HERSCHBACH DR
Title:	DIMENSIONAL SINGULARITY ANALYSIS OF RELATIVISTIC-EQUATIONS
Source:	PHYSICAL REVIEW A 1991, Vol 43, Iss 9, pp 4617-4624
No. cited references:	42
Addresses:	GOODSON DZ, HARVARD UNIV, DEPT CHEM, CAMBRIDGE, MA 02138. HARVARD SMITHSONIAN CTR ASTROPHYS, INST THEORET ATOM & MOLEC PHYS, CAMBRIDGE, MA 02138.
KeywordsPlus:	LARGE-N EXPANSION; 2-ELECTRON ATOMS; SCHRODINGER-EQUATION; PERTURBATION-THEORY; VARIABLE DIMENSIONALITY; CLASSICAL MECHANICS; QUANTUM-MECHANICS; HYDROGEN-ATOM; 1/N EXPANSION; ENERGY-LEVELS
Abstract:	For a nonrelativistic hydrogenic atom, the dimension dependence of the energy levels is non-singular except for a second-order pole at D* = 3 - 2n, where n is the principal quantum number. For the relativistic Klein-Gordon and Dirac equations, the dimension dependence has a much more complicated singularity structure, involving branch points. For all eigenstates there are branch points at D+ +/- 2Z-alpha, where Z is the nuclear charge, alpha is the fine-structure constant, and D+ is independent of n but varies linearly with orbital angular momentum. For most states there is in addition a pair of branch points near D* but slightly off the real axis. The customary perturbation expansion in terms of Z-alpha gives qualitatively incorrect dimension dependence; it predicts only poles located on the real axis at D* and D+, no matter how high the order of the expansion. The dimensional singularities result from the behavior at r = 0. The qualitatively incorrect results occur because the perturbing potential, proportional to alpha-2/r2, overwhelms the unperturbed 1/r potential at small r. Because of the complexity of the dimensional singularity structure, the popular "shifted expansion" method for summing the 1/D expansion does not work well for these equations. We demonstrate a general method for identifying the dimensional singularities that leads to an exact summation of the 1/D expansion for all eigenstates of both the Klein-Gordon and the Dirac equations for a particle in a Coulomb potential.
Cited references:	ADER JP-1983-PHYS-LETT-A-V97-P178 AVERY J-IN-PRESS-THEOR-CHIM BAKER GA-1981-ENCY-MATH-ITS-APPLIC-V14 BAKER GA-1981-ENCY-MATH-ITS-APPLIC-V13 BAKER JD-1990-PHYS-REV-A-V41-P1247 BAYM G-1973-LECTURES-QUANTUM-MEC-P563 BENDER CM-1982-PHYS-REV-A-V25-P1305 BERVILLIER C-1978-PHYS-REV-D-V17-P2144 CHATTERJEE A-1990-PHYS-REP-V186-P249 DOREN DJ-1985-CHEM-PHYS-LETT-V118-P115 DOREN DJ-1987-J-CHEM-PHYS-V87-P433 DOREN DJ-1986-J-CHEM-PHYS-V85-P4557 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DOREN DJ-1986-PHYS-REV-A-V34-P2665 FRANTZ DD-1988-CHEM-PHYS-V126-P59 GOODSON DZ-1987-J-CHEM-PHYS-V86-P4997 GOODSON DZ-1987-PHYS-REV-LETT-V58-P1631 GOSCINSKI O-1986-INT-J-QUANTUM-CHEM-V29-P897 HERRICK DR-1975-J-MATH-PHYS-V16-P281 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1989-AT-PHYS-V11-P63 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HERSCHBACH DR-1988-Z-PHYS-D-ATOM-MOL-CL-V10-P195 KATO T-1966-PERTURBATION-THEORY LOESER JG-1987-J-CHEM-PHYS-V86-P2114 LOESER JG-1987-J-CHEM-PHYS-V86-P5635 LOESER JG-1985-J-PHYS-CHEM-US-V89-P3444 MARTIN PC-1958-PHYS-REV-V109-P1307 MIRAMONTES JL-1984-NUOVO-CIMENTO-B-V84-P10 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 NIETO MM-1979-AM-J-PHYS-V47-P1067 PANJA MM-1990-PHYS-REV-A-V42-P106 PANJA MM-1988-PHYS-REV-A-V38-P3937 POPOV VS-1986-SOV-J-NUCL-PHYS+-V44-P714 ROSENTHAL CM-1971-J-CHEM-PHYS-V55-P2474 ROYCHOUDHURY R-1989-PHYS-REV-A-V39-P5523 SUKHATME U-1983-PHYS-REV-D-V28-P418 VAINBERG VM-1986-JETP-LETT+-V44-P9 VANDERMERWE PD-1988-PHYS-REV-A-V38-P1187 WITTEN E-1980-NATO-ADV-STUDY-I-S-B-V59 WITTEN E-1980-PHYS-TODAY-V33-P38 YAFFE LG-1982-REV-MOD-PHYS-V54-P407
Source item page count:	8
Publication Date:	MAY 1
IDS No.:	FL111
29-char source abbrev:	PHYS REV A

Record 60 of 74
Author(s):	KOLOSOV VV
Title:	THE STARK RESONANCES NEAR ZERO ENERGY
Source:	JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS 1991, Vol 24, Iss 7, pp L185-L188
No. cited references:	14
Addresses:	KOLOSOV VV, ACAD SCI LASSR, INST PHYS, SALASPILS 229021, LATVIA, USSR.
KeywordsPlus:	UNIFORM ELECTRIC-FIELD; HYDROGEN-ATOM; INTERFERENCE PHENOMENA; PERTURBATION-THEORY; STATES; PHOTOIONIZATION; PHOTOIONISATION
Abstract:	Simple formulae for the energies and widths of the Stark levels in the neighbourhood of the zero-field ionization threshold are deduced. Comparison with the results of exact numerical calculation shows that the formulae obtained are of high accuracy for both the negative and positive energy regions.
Cited references:	ABRAMOWITZ M-1964-HDB-MATH-FUNCTIONS ALVAREZ G-1989-PHYS-REV-LETT-V63-P1367 BEKENSTEIN JD-1969-PHYS-REV-V188-P130 FERANCHUK ID-1989-PHYS-LETT-A-V137-P385 GLAB WL-1985-PHYS-REV-A-V31-P3677 KAZANSKY AK-1990-J-PHYS-B-AT-MOL-OPT-V23-PL433 KOLOSOV VV-1989-J-PHYS-B-AT-MOL-OPT-V22-P833 KOLOSOV VV-1988-OPT-SPEKTROSK+-V65-P251 KONDRATOVICH VD-1990-J-PHYS-B-AT-MOL-OPT-V23-P21 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P1981 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P2011 MUR VD-1989-ZH-EKSP-TEOR-FIZ+-V96-P91 NG K-1987-PHYS-REV-A-V35-P2508 ROTTKE H-1986-PHYS-REV-A-V33-P301
Source item page count:	4
Publication Date:	APR 14
IDS No.:	FJ566
29-char source abbrev:	J PHYS-B-AT MOL OPT PHYS

Record 61 of 74
Author(s):	KONDRATOVICH VD; OSTROVSKY VN
Title:	RESONANCE AND INTERFERENCE PHENOMENA IN THE PHOTOIONIZATION OF A HYDROGEN-ATOM IN A UNIFORM ELECTRIC-FIELD .4. DIFFERENTIAL CROSS-SECTIONS
Source:	JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS 1990, Vol 23, Iss 21, pp 3785-3809
No. cited references:	16
Addresses:	KONDRATOVICH VD, VINNITSA POLYTECH INST, VINNITSA 286021, UKRAINE, USSR. LENINGRAD STATE UNIV, LENINGRAD 198904, USSR.
Cited references:	BERRY MV-1982-J-PHYS-A-MATH-GEN-V15-PL385 DEMKOV YN-1981-JETP-LETT+-V34-P403 FABRIKANT II-1980-ZH-EKSP-TEOR-FIZ+-V52-P1045 FEYNMAN RP-1977-LECTURES-PHYSICS-V3 FREEMAN RR-1979-PHYS-REV-A-V20-P2356 GLAB WL-1985-PHYS-REV-A-V31-P530 KONDRATOVICH VD-1990-J-PHYS-B-AT-MOL-OPT-V23-P21 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P1981 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P2011 KONDRATOVICH VD-1986-PROBLEMS-THEORY-ATOM-V3-P165 LANDAU LD-1965-QUANTUM-MECHANICS LIBERMAN S-1979-PHYS-REV-A-V20-P507 MANAKOV NL-1986-PHYS-REP-V141-P319 ROTTKE H-1986-PHYS-REV-A-V33-P301 WEINBERG VM-1987-JETP-LETT+-V46-P178 WEINBERG VM-1987-ZH-EKSP-TEOR-FIZ+-V93-P450
Source item page count:	25
Publication Date:	NOV 14
IDS No.:	EJ065
29-char source abbrev:	J PHYS-B-AT MOL OPT PHYS

Record 62 of 74
Author(s):	MUR VD; POPOV VS
Title:	QUANTIZATION WITH ALLOWANCE FOR THE BARRIER PENETRATION
Source:	JETP LETTERS 1990, Vol 51, Iss 10, pp 563-567
No. cited references:	6
Addresses:	MUR VD, MOSCOW THEORET & EXPTL PHYS INST, MOSCOW, USSR.
Cited references:	BEKENSTEIN JD-1969-PHYS-REV-V188-P130 DUNHAM JL-1932-PHYS-REV-V41-P713 LANDAU LD-1977-QUANTUM-MECHANICS LISITSA VS-1987-SOV-PHYS-USP-V30-P195 VAINBERG VM-1986-JETP-LETT+-V44-P9 VAINBERG VM-1987-ZH-EKSP-TEOR-FIZ+-V66-P258
Source item page count:	5
Publication Date:	MAY 25
IDS No.:	DW030
29-char source abbrev:	JETP LETT-ENGL TR

Record 63 of 74
Author(s):	KONDRATOVICH VD; OSTROVSKY VN
Title:	RESONANCE AND INTERFERENCE PHENOMENA IN THE PHOTIONISATION OF A HYDROGEN-ATOM IN A UNIFORM ELECTRIC-FIELD .3. COMPARISON WITH RECENT EXPERIMENTAL AND THEORETICAL RESULTS
Source:	JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS 1990, Vol 23, Iss 1, pp 21-43
No. cited references:	31
Addresses:	KONDRATOVICH VD, VINNITSA POLYTECH INST, VINNITSA 286021, UKRAINE, USSR. LENINGRAD STATE UNIV, LENINGRAD 198904, USSR.
Cited references:	ANSELM AI-1978-VVEDENIE-TEORIYU-POL BERGEMAN T-1984-PHYS-REV-LETT-V53-P775 BRYANT HC-1987-PHYS-REV-LETT-V58-P2412 DACHKOV LG-1987-OPT-SPEKTROSK+-V63-P250 DACHKOV LG-1986-OPT-SPEKTROSK+-V61-P688 DAMBURG RJ-1987-LAFI108-SAL-PREPR FABRIKANT II-1980-ZH-EKSP-TEOR-FIZ+-V52-P1045 FANO U-1961-PHYS-REV-V124-P1866 FENEUILLE S-1979-PHYS-REV-LETT-V42-P1404 FREEMAN RR-1978-PHYS-REV-LETT-V41-P1463 GLAB WL-1985-PHYS-REV-A-V31-P530 GLAB WL-1985-PHYS-REV-A-V31-P3677 HARMIN DA-1985-PHYS-REV-A-V31-P2984 HARMIN DA-1982-PHYS-REV-A-V26-P2656 HARMIN DA-1981-PHYS-REV-A-V24-P2491 KOENIG EL-1980-J-PHYS-B-ATOM-MOL-PH-V13-P1743 KOENIG EL-1980-J-PHYS-B-ATOM-MOL-PH-V13-P1769 KOLOSOV VV-1986-JETP-LETT+-V44-P457 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P1981 KONDRATOVICH VD-1984-J-PHYS-B-AT-MOL-OPT-V17-P2011 KONDRATOVICH VD-1983-ZH-EKSP-TEOR-FIZ+-V56-P719 KONDRATOVICH VD-1981-ZH-EKSP-TEOR-FIZ+-V52-P198 LUK TS-1981-PHYS-REV-LETT-V47-P83 MORSE PM-1953-METHODS-THEORETICA-1-PCH4 POPOV VS-1987-ATOMINFORM-N182-PREP RAU ARP-1980-PHYS-REV-A-V21-P1057 REINHARDT WP-1983-J-PHYS-B-AT-MOL-OPT-V16-PL635 ROTTKE H-1986-PHYS-REV-A-V33-P301 STEWART JE-1987-LA11152T-LOS-AL WEINBERG VM-1987-JETP-LETT+-V46-P178 WEINBERG VM-1987-ZH-EKSP-TEOR-FIZ+-V93-P450
Source item page count:	23
Publication Date:	JAN 14
IDS No.:	CJ109
29-char source abbrev:	J PHYS-B-AT MOL OPT PHYS

Record 64 of 74
Author(s):	MUR VD; POZDNIAKOV SG; POPOV VS
Title:	1/N-EXPANSION AND WAVE-FUNCTION CALCULATION
Source:	DOKLADY AKADEMII NAUK SSSR 1988, Vol 303, Iss 5, pp 1102-1107
No. cited references:	8
Cited references:	1986-YADERNAYA-FIZIKA-V44-P1103 EICHTEN E-1978-PHYS-REV-D-V17-P3090 ELETSKII VL-1979-DOKL-AKAD-NAUK-SSSR+-V249-P329 IMBO T-1985-PHYS-REV-D-V31-P2655 MUR VD-1987-JETP-LETT+-V45-P323 POPOV VS-1985-JETP-LETT+-V41-P439 VAINBERG VM-1986-JETP-LETT+-V44-P9 WITTEN E-1980-RECENT-DEV-GAUGE-THE
Source item page count:	6
IDS No.:	T0476
29-char source abbrev:	DOKL AKAD NAUK SSSR

Record 65 of 74
Author(s):	MUR VD; POPOV VS
Title:	SCALING FOR THE STARK-EFFECT IN THE RYDBERG ATOMS
Source:	JETP LETTERS 1988, Vol 48, Iss 2, pp 70-74
No. cited references:	10
Addresses:	MUR VD, MOSCOW THEORET & EXPTL PHYS INST, MOSCOW, USSR.
Cited references:	BEKENSTEIN JD-1969-PHYS-REV-V188-P130 FREEMAN RR-1979-PHYS-REV-A-V20-P2356 GLAB WL-1985-PHYS-REV-A-V31-P3677 KOLOSOV VV-1986-JETP-LETT+-V44-P588 LANDAU LD-1977-QUANTUM-MECHANICS LUK TS-1981-PHYS-REV-LETT-V47-P83 NG K-1987-PHYS-REV-A-V35-P2508 RADTSIG AA-1986-PARAMETERS-ATOMS-ATO SANDNER W-1981-PHYS-REV-A-V23-P2448 VAINBERG VM-1987-JETP-LETT+-V46-P225
Source item page count:	5
Publication Date:	JUL 25
IDS No.:	R6958
29-char source abbrev:	JETP LETT-ENGL TR

Record 66 of 74
Author(s):	BOGOMOLNYI EG
Title:	OSCILLATION OF THE PHOTOABSORPTION NEAR THE IONIZATION THRESHOLD FOR HYDROGEN-LIKE ATOMS IN ELECTRIC AND MAGNETIC-FIELDS
Source:	JETP LETTERS 1988, Vol 47, Iss 9, pp 526-529
No. cited references:	10
Addresses:	BOGOMOLNYI EG, LD LANDAU THEORET PHYS INST, MOSCOW, USSR.
Cited references:	BETHE H-1958-QUANTUM-MECHANICS-ON BOGOMOLNY EB-1987-LANDAU-I-PREPRINT-P21 BOGOMOLNYI EB-1986-JETP-LETT+-V44-P561 GUTZWILLER MC-1971-J-MATH-PHYS-V12-P343 HOLLE A-1986-PHYS-REV-LETT-V56-P2594 MAIN J-1986-PHYS-REV-LETT-V57-P2789 NG K-1987-PHYS-REV-A-V35-P2508 ROTTKE H-1986-PHYS-REV-A-V33-P301 VAINBERG VM-1987-JETP-LETT+-V46-P225 WINTGEN D-1987-PHYS-REV-A-V36-P131
Source item page count:	4
Publication Date:	MAY 10
IDS No.:	R1245
29-char source abbrev:	JETP LETT-ENGL TR

Record 67 of 74
Author(s):	MUR VD; POPOV VS
Title:	THE 1/N EXPANSION AND WAVE-FUNCTIONS
Source:	SOVIET JOURNAL OF NUCLEAR PHYSICS-USSR 1988, Vol 47, Iss 3, pp 444-449
No. cited references:	29
Addresses:	MOSCOW THEORET & EXPTL PHYS INST, MOSCOW, USSR.
Cited references:	BADALYAN AM-1987-NUCL-PHYS-B-V281-P85 BENDER CM-1982-PHYS-REV-A-V25-P1305 BURKE PG-1977-POTENTIAL-SCATTERING DOLGOV AD-1979-ITEF72-I-THEOR-EXP-P DOLGOV AD-1979-PHYS-LETT-B-V86-P185 DRUKAREV GF-1981-SOV-PHYS-JETP-V53-P271 EICHTEN E-1978-PHYS-REV-D-V17-P3090 GOLDBERGER ML-1964-COLLISION-THEORY IMBO T-1984-PHYS-LETT-A-V105-P183 IMBO T-1985-PHYS-REV-D-V31-P2655 IMBO T-1984-PHYS-REV-D-V29-P1669 KUDRJAVTSEV AE-1984-PHYS-LETT-B-V143-P41 KUDRYAVTSEV AE-1983-JETP-LETT+-V37-P489 MLODINOW LD-1981-ANN-PHYS-NEW-YORK-V131-P1 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 MUR VD-1985-ITEP84-I-THEOR-EXP-P MUR VD-1983-SOV-J-NUCL-PHYS+-V37-P844 MUR VD-1976-THEOR-MATH-PHYS+-V27-P429 POPOV VS-1986-ITEP125-I-THEOR-EXP POPOV VS-1985-JETP-LETT+-V41-P539 POPOV VS-1986-SOV-J-NUCL-PHYS+-V44-P714 POPOV VS-1985-SOV-PHYS-JETP-V61-P420 QUIGG C-1979-PHYS-REP-V56-P167 SHAPIRO IS-1978-PHYS-REP-V35-P129 SHAPIRO IS-1962-SOV-PHYS-JETP-V14-P1148 SHAPIRO IS-1963-THEORY-DIRECT-NUCLEA SUKHATME U-1983-PHYS-REV-D-V28-P418 VAINBERG VM-1986-JETP-LETT+-V44-P9 WITTEN E-1980-RECENT-DEV-GAUGE-THE
Source item page count:	6
Publication Date:	MAR
IDS No.:	Q5571
29-char source abbrev:	SOV J NUCL PHYS-ENGL TR

Record 68 of 74
Author(s):	VRSCAY ER; HAMIDIAN H
Title:	RAYLEIGH-SCHRODINGER PERTURBATION-THEORY AT LARGE ORDER FOR RADIAL RELATIVISTIC HAMILTONIANS USING HYPERVIRIAL AND HELLMANN-FEYNMAN THEOREMS
Source:	PHYSICS LETTERS A 1988, Vol 130, Iss 3, pp 141-146
No. cited references:	34
Addresses:	VRSCAY ER, UNIV WATERLOO, DEPT APPL MATH, WATERLOO N2L 3G1, ONTARIO, CANADA.
Cited references:	1982-INT-J-QUANTUM-CHEM-V21 AU CK-1980-PHYS-REV-A-V22-P1820 BAKER GA-1975-ESSENTIALS-PADE-APPR CHAR BW-1985-MAPLE-USERS-GUIDE CIZEK J-1977-INT-J-QUANTUM-CHEM-V12-P875 CRITCHFIELD CL-1976-J-MATH-PHYS-V17-P261 EPSTEIN JH-1962-AM-J-PHYS-V30-P266 EPSTEIN ST-1976-AM-J-PHYS-V44-P251 EPSTEIN ST-1961-PHYSICAL-REVIEW-V123-P1495 ERDELYI A-1956-ASYMPTOTIC-EXPANSION FERNANDEZ FM-1987-LECTURE-NOTES-CHEM-V43 FEYNMAN RP-1939-PHYS-REV-V56-P340 FOCK V-1930-Z-PHYSIK-V61-P126 GOLDMAN T-1975-PHYS-REV-D-V12-P2910 GRANT M-1979-PHYS-REV-A-V20-P718 GREINER W-1985-QUANTUM-ELECTRODYNAM HALL RL-1987-J-MATH-PHYS-V26-P457 HELLMANN H-1937-EINFUHRUNG-QUANTENCH HENRICI P-1977-APPLIED-COMPUTATIONA-V2 HIRSCHFELDER JO-1970-J-CHEM-PHYS-V33-P1762 KILLINGBECK J-1978-PHYS-LETT-A-V65-P87 LAI CS-1982-J-PHYS-A-MATH-GEN-V15-PL155 MCENNAN J-1977-PHYS-REV-A-V16-P1768 MCKINLEY WA-1971-AM-J-PHYS-V39-P905 MOORE RA-1975-CAN-J-PHYS-V53-P1240 SCHIFF LI-1955-QUANTUM-MECHANICS SERGEEV AV-1984-SOV-J-NUCL-PHYS+-V39-P731 SHERSTYUK AI-1972-SOV-PHYS-JETP-V35-P655 SIMON B-1970-ANN-PHYS-V58-P76 SOFF G-1973-Z-NATURFORSCH-A-VA 28-P1389 SWENSON RJ-1972-J-CHEM-PHYS-V57-P1734 VRSCAY ER-1985-J-MATH-PHYS-V27-P185 VRSCAY ER-1986-PHYS-REV-A-V33-P1433 VRSCAY ER-1985-PHYS-REV-A-V31-P2054
Source item page count:	6
Publication Date:	JUL 4
IDS No.:	P2323
29-char source abbrev:	PHYS LETT A

Record 69 of 74
Author(s):	PAPP E
Title:	QUASICLASSICAL SYMMETRY PROPERTIES .2.
Source:	PHYSICS REPORTS-REVIEW SECTION OF PHYSICS LETTERS 1988, Vol 161, Iss 4, pp 171-212
No. cited references:	141
Addresses:	PAPP E, TECH UNIV CLAUSTHAL, INST THEORET PHYS, D-3392 CLAUSTHAL ZELLERFE, FED REP GER.
Cited references:	ADAMOWSKI J-1985-PHYS-REV-A-V31-P43 ALHASSID Y-1985-PHYS-REV-LETT-V54-P1746 ARTECA GA-1984-J-MATH-PHYS-V25-P932 AU CK-1979-PHYS-REV-A-V20-P2245 BALSLEV E-1971-COMM-MATH-P-V22-P280 BARUT AO-1967-PHYS-REV-V156-P1541 BARUT AO-1971-PHYS-REV-D-V3-P1747 BARUT AO-1974-PHYS-REV-D-V10-P2709 BENDER CM-1982-PHYS-REV-A-V25-P1305 BENJAMIN I-1986-PHYS-REV-A-V33-P2833 BJORKEN JD-1964-RELATIVISTIC-QUANTUM BOHM D-1987-PHYS-REP-V144-P321 BOHM D-1952-PHYS-REV-V85-P166 BOHM D-1952-PHYS-REV-V85-P180 BOHM D-1954-PHYSICAL-REVIEW-V96-P208 BOPP F-1965-ANN-PHYSIK-V17-P407 BOSE SK-1985-J-PHYS-A-MATH-GEN-V18-P1289 BRANDAS E-1977-PHYS-REV-A-V16-P2207 BUSIELLO G-1986-J-PHYS-A-MATH-GEN-V19-PL881 CEROFOLINI GF-1980-NUOVO-CIMENTO-B-V58-P286 CHATTERJEE A-1986-J-MATH-PHYS-V27-P2331 CHATTERJEE A-1986-J-PHYS-A-V18-P3707 CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P1193 CHATTERJEE A-1987-PHYS-REV-A-V35-P2722 CHATTERJEE A-1986-PHYS-REV-A-V34-P2470 CRITCHFIELD CL-1976-J-MATH-PHYS-V17-P261 DEBROGLIE L-1927-COMPT-REND-V185-P380 DEBROGLIE L-1927-COMPT-REND-V184-P273 DEBROGLIE L-1926-COMPT-REND-V183-P447 DELAPENAAUERBACL-1969-J-MATH-PHYS-V10-P1620 DOGLOV AD-1978-PHYS-LETT-B-V79-P403 DOLGOV AD-1979-PHYS-LETT-B-V86-P185 DOOLEN GD-1975-J-PHYS-B-AT-MOL-OPT-V8-P525 DOREN DJ-1986-PHYS-REV-A-V34-P2654 DUMONTLEPAGE MC-1980-J-PHYS-A-MATH-GEN-V13-P1243 DUTT R-1987-J-PHYS-B-AT-MOL-OPT-V20-P2437 DUTT R-1986-PHYS-REV-A-V34-P777 EHRENFEST P-1920-ANN-PHYS-LEIPZIG-V61-P440 EISENHART LP-1948-PHYS-REV-V74-P87 ELETSKY VL-1981-PHYS-LETT-A-V84-P235 ESEBBAG C-1985-J-PHYS-A-MATH-GEN-V18-P3505 FELDMAN G-1979-NUCL-PHYS-B-V154-P441 FENYES I-1952-Z-PHYS-V132-P81 FERNANDEZ FM-1987-PHYS-REV-A-V35-P4861 FERNANDEZ FM-1983-PHYS-REV-A-V27-P663 FERNANDEZ FM-1983-PHYS-REV-A-V27-P2735 FEYNMAN RP-1939-PHYS-REV-V56-P340 FOCK V-1930-Z-PHYSIK-V63-P855 FRYE D-1986-PHYS-REV-A-V34-P1682 GERRY CC-1986-J-PHYS-A-MATH-GEN-V19-P3797 GRANT M-1979-PHYS-REV-A-V20-P718 GREEN AES-1986-PHYS-REV-A-V33-P2087 HALL RL-1985-PHYS-REV-A-V32-P14 HALLIDAY IG-1980-PHYS-REV-D-V21-P1529 HELLMANN H-1935-ACTA-FIZICOCHIM-USSR-V1-P913 HELLMANN H-1936-ACTA-PHYSICOCHIM-URS-V4-P225 HELLMANN H-1935-J-CHEM-PHYSICS-V3-P61 HO YK-1983-PHYS-REP-V99-P1 IMBO T-1984-PHYS-LETT-A-V105-P183 IMBO T-1984-PHYS-REV-D-V29-P1669 JACOBS S-1986-PHYS-REV-D-V33-P3338 JUNKER BR-1983-PHYS-REV-A-V27-P2785 JUNKER BR-1978-PHYS-REV-A-V18-P313 JUNKER BR-1978-PHYS-REV-A-V18-P2437 KAZAMA Y-1977-PHYS-REV-D-V15-P2287 KAZAMA Y-1977-PHYS-REV-D-V15-P2300 KERSHAW D-1964-PHYSICAL-REVIEW-B-V136-P1850 KIBLER M-1987-J-PHYS-A-MATH-GEN-V20-P4097 KIBLER M-1984-PHYS-REV-A-V29-P2891 KILLINGBECK J-1979-REP-PROG-PHYS-V40-P963 KLAUDER JR-1987-ANN-PHYS-NEW-YORK-V180-P108 KOSTIN MD-1975-J-STAT-PHYS-V12-P145 KUSTAANHEIMO P-1965-J-REINE-ANGEWANDTE-M-V218-P204 LAI CH-1987-J-MATH-PHYS-V28-P1801 LANDAU LD-1959-QUANTUM-MECHANICS LISSIA M-1986-NUOVO-CIMENTO-A-V92-P217 LITTLEJOHN RG-1987-PHYS-REV-A-V36-P2953 MADELUNG E-1926-Z-PHYS-V40-P322 MAKI JN-1986-PHYS-REV-LETT-V57-P2097 MALKIN IA-1965-JETP-LETT-V2-P146 MALKUS WVR-1951-PHYSICAL-REVIEW-V83-P899 MALUENDES SA-1987-PHYS-LETT-A-V124-P215 MARRIWALLA KH-1975-PHYS-REP-V20-P287 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MORENO G-1984-J-PHYS-B-AT-MOL-OPT-V17-P21 MUR VD-1987-JETP-LETT-V45-P411 MYUNG HC-1982-HADRONIC-J-V5-P1277 MYUNG HC-1982-HADRONIC-J-V5-P1367 NASSAR AB-1986-PHYS-REV-A-V33-P2134 NASSAR AB-1986-PHYS-REV-A-V33-P3502 NELSON E-1966-PHYSICAL-REVIEW-V150-P1079 NIETO MM-1979-AM-J-PHYS-V47-P1067 NISHIOKA M-1983-NUOVO-CIMENTO-B-V77-P19 ORLAND H-1979-PHYS-REV-LETT-V42-P285 OSLAND P-1984-NUCL-PHYS-B-V247-P421 OSLAND P-1984-NUCL-PHYS-B-V247-P450 PAPP E-1986-PHYS-LETT-A-V118-P167 PAPP E-1986-PHYS-REP-V136-P103 PAPP E-1988-PHYS-REV-A-V37 PAPP E-1987-PHYS-REV-A-V36-P3550 PAPP E-1987-PHYS-REV-A-V35-P4946 PAPP E-1986-PHYS-REV-A-V34-P47 PAPP E-1986-PHYS-REV-A-V34-P4405 PAPP E-1986-PHYS-REV-A-V33-P719 POPOV VS-1986-YAD-FIZ-V44-P1103 PRUGOVECKI E-1984-STOCHASTIC-QUANTUM-M QUESNE C-1986-J-PHYS-A-MATH-GEN-V19-P2689 QUIGG C-1979-PHYS-REP-V56-P167 REBANE TK-1983-TEORETICHESKAYA-MATE-V56-P432 ROBICHEAUX F-1987-PHYS-REV-A-V35-P3619 ROGERS FJ-1970-PHYS-REV-A-V1-P1577 ROSEN G-1987-J-MATH-PHYS-V28-P975 ROSEN G-1986-PHYS-REV-A-V34-P1556 ROSEN G-1979-PHYS-REV-A-V20-P1287 ROSENAU P-1986-PHYS-LETT-A-V114-P355 ROWLEY N-1979-J-PHYS-A-MATH-GEN-V12-PL7 ROY B-1987-J-PHYS-A-MATH-GEN-V20-P3051 ROYCHOUDHURY RK-1987-J-PHYS-A-MATH-GEN-V20-PL1083 SANTILLI RM-1983-LETT-NUOVO-CIMENTO-V38-P509 SCHRODINGER E-1941-P-ROY-IRISH-ACAD-A-V46-P183 SCHWINGER J-1976-ANN-PHYS-NEW-YORK-V101-P451 SEVER R-1987-PHYS-REV-A-V36-P1045 SEVER R-1987-PHYS-REV-A-V35-P2725 SILVERMAN JN-1970-CHEM-PHYS-LETT-V7-P37 SILVERMAN JN-1970-CHEM-PHYS-LETT-V7-P640 SOFF G-1973-Z-NATURFORSCH-A-VA 28-P1389 SOMMERFELD A-1949-PARTIAL-DIFFERENTIAL SUKHATME U-1983-PHYS-REV-D-V28-P418 TANG AZ-1987-PHYS-REV-A-V35-P911 TANGHERLINE FR-1963-NUOVO-CIMENTO-V27-P636 TURBINER AV-1980-SOV-PHYS-JETP-V52-P868 VAINBERG VM-1986-JETP-LETT+-V44-P9 VANDERMERWE PD-1986-PHYS-REV-D-V33-P3383 VARSHNI YP-1987-PHYS-REV-A-V36-P3009 VICHARELLI PA-1987-PHYS-REV-A-V35-P1477 WANG YY-1987-J-PHYS-PARIS-V48-P2067 WEIZEL W-1953-Z-PHYS-V134-P264 YAFFE LG-1982-REV-MOD-PHYS-V54-P407 YARIS R-1978-J-PHYS-B-AT-MOL-OPT-V11-P1475 YASUE K-1978-ANN-PHYS-NEW-YORK-V114-P479
Source item page count:	42
Publication Date:	APR
IDS No.:	N1086
29-char source abbrev:	PHYS REP-REV SECT PHYS LETT

Record 70 of 74
Author(s):	MUR VD; POPOV VS
Title:	1/N EXPANSION AND WAVE-FUNCTIONS
Source:	JETP LETTERS 1987, Vol 45, Iss 7, pp 410-413
No. cited references:	15
Addresses:	MUR VD, MOSCOW THEORET & EXPTL PHYS INST, MOSCOW, USSR.
Cited references:	BADALYAN AM-1987-NUCL-PHYS-B-V281-P85 BENDER CM-1982-PHYS-REV-A-V25-P1305 BURKE PG-1977-POTENTIAL-SCATTERING DOLGOV AD-1979-ITEF72-I-THEOR-EXP-P DOLGOV AD-1979-PHYS-LETT-B-V86-P185 EICHTEN E-1978-PHYS-REV-D-V17-P3090 IMBO T-1984-PHYS-LETT-A-V105-P183 IMBO T-1985-PHYS-REV-D-V31-P2655 MUR VD-1983-SOV-J-NUCL-PHYS+-V37-P844 MUR VD-1976-TEOR-MAT-FIZ-V27-P204 POPOV VS-1985-JETP-LETT+-V41-P539 SHAPIRO IS-1978-PHYS-REP-V35-P129 SUKHATME U-1983-PHYS-REV-D-V28-P418 VAINBERG VM-1986-JETP-LETT+-V44-P9 WITTEN E-1980-RECENT-DEV-GAUGE-THE
Source item page count:	4
Publication Date:	APR 10
IDS No.:	J7197
29-char source abbrev:	JETP LETT-ENGL TR

Record 71 of 74
Author(s):	DOREN DJ; HERSCHBACH DR
Title:	SPATIAL DIMENSION AS AN EXPANSION PARAMETER IN QUANTUM-MECHANICS
Source:	PHYSICAL REVIEW A 1986, Vol 34, Iss 4, pp 2654-2664
No. cited references:	40
Addresses:	DOREN DJ, HARVARD UNIV, DEPT CHEM, CAMBRIDGE, MA 02138.
Cited references:	ABRAMOWITZ M-1964-APPLIED-MATH-SERIES-V55 AMIT DJ-1978-FIELD-THEORY-RENORMA BALIAN R-1974-ANN-PHYS-NEW-YORK-V83-P28 BALIAN R-1973-PHYS-REV-LETT-V30-P544 BENDER CM-1982-PHYS-REV-A-V25-P1305 BENDER CM-1969-PHYSICAL-REVIEW-V184-P1231 CHATTERJEE A-1985-J-PHYS-A-MATH-GEN-V18-P1193 DOLGOV AD-1979-ITEF72-I-THEOR-EXP-P DOLGOV AD-1979-PHYS-LETT-B-V86-P185 DOLGOV AD-1978-PHYS-LETT-B-V79-P403 DOMB C-1976-PHASE-TRANSITIONS-CR-V6 DOREN DJ-1985-CHEM-PHYS-LETT-V118-P115 DOREN DJ-1986-PHYS-REV-A-V34-P2665 DOREN DJ-UNPUB-J-CHEM-PHYS EICHTEN E-1978-PHYS-REV-D-V17-P3090 ELETSKY VL-1980-PHYS-LETT-B-V94-P65 FERRELL RA-1974-PHYS-REV-A-V9-P846 FISHER ME-1973-PHYS-REV-LETT-V30-P679 GAZEAU JP-1979-PHYS-REV-A-V20-P727 GELFAND IM-1964-GENERALIZED-FUNCTION-V1 HERRICK DR-1975-PHYS-REV-A-V11-P42 HERSCHBACH DR-1986-J-CHEM-PHYS-V84-P838 HIKAMI S-1979-J-PHYS-A-MATH-GEN-V12-P759 HILL RN-1985-J-CHEM-PHYS-V83-P1173 KNOPS HJF-1973-PHYS-LETT-A-VA 45-P217 KOUDINOV AV-1982-CZECH-J-PHYS-V32-P556 MLODINOW LD-1981-ANN-PHYS-NEW-YORK-V131-P1 MLODINOW LD-1980-ANN-PHYS-NEW-YORK-V128-P314 MLODINOW LD-1984-J-MATH-PHYS-V25-P943 MORENO G-1984-J-PHYS-B-AT-MOL-OPT-V17-P21 PRIVMAN V-1981-PHYS-LETT-A-V81-P326 ROGERS FJ-1970-PHYS-REV-A-V1-P1577 SERGEEV AV-1982-ZH-EKSP-TEOR-FIZ+-V82-P1070 SINHAROY M-1984-J-PHYS-A-MATH-GEN-V17-PL687 VANDERMERWE PI-1983-LETT-NUOVO-CIMENTO-V37-P86 VRSCAY ER-1986-PHYS-REV-A-V33-P1433 WITTEN E-1980-PHYS-TODAY-V33-P38 YAFFE LG-1983-PHYS-TODAY-V36-P50 YAFFE LG-1982-REV-MOD-PHYS-V54-P407 ZINNJUSTIN J-1981-J-MATH-PHYS-V22-P511
Source item page count:	11
Publication Date:	OCT
IDS No.:	E2344
29-char source abbrev:	PHYS REV A

Record 72 of 74
Author(s):	POPOV VS; WEINBERG VM
Title:	ON SUMMATION OF PERTURBATION-SERIES FOR SCREENED COULOMB POTENTIALS
Source:	PHYSICS LETTERS A 1985, Vol 107, Iss 8, pp 371-375
No. cited references:	35
Addresses:	POPOV VS, MOSCOW THEORET & EXPTL PHYS INST, MOSCOW 117259, USSR.
Cited references:	ALLILUEV SP-1982-DOKL-AKAD-NAUK-SSSR+-V265-P597 ALLILUEV SP-1979-PHYS-LETT-A-V73-P103 AU CK-1979-PHYS-REV-A-V20-P2245 AU CK-1979-PHYS-REV-LETT-V42-P1582 BENDER CM-1973-PHYS-REV-D-V7-P1620 BENDER CM-1969-PHYSICAL-REVIEW-V184-P1231 BOGOMOLNY E-1980-SOVIET-SCI-REV-A-V2-P247 DOLGOV AD-1979-PHYS-LETT-B-V86-P185 DOLGOV AD-1978-PHYS-LETT-B-V79-P403 DOLGOV AD-1980-ZH-EKSP-TEOR-FIZ+-V79-P1704 DOLGOV AD-1978-ZH-EKSP-TEOR-FIZ+-V75-P2010 DYSON FJ-1952-PHYS-REV-V85-P631 EICHTEN E-1978-PHYS-REV-D-V17-P3090 ELETSKY VL-1983-ITEP179-PREPR ELETSKY VL-1981-PHYS-LETT-A-V84-P235 ELETSKY VL-1982-SOV-PHYS-JETP-V54-P833 GRAFFI S-1971-NUOVO-CIMENTO-B-V4-P313 KESARWANI RN-1978-J-MATH-PHYS-V19-P819 LAI CS-1982-PHYS-REV-A-V26-P2245 LAI CS-1981-PHYS-REV-A-V23-P455 LIPATOV LN-1977-SOV-PHYS-JETP-V45-P216 LIPATOV LN-1976-SOVIET-PHYSICS-JETP-V44-P1055 ORLOV YV-1984-ZH-EKSP-TEOR-FIZ-V86-P1598 POPOV VS-1983-DOKL-AKAD-NAUK-SSSR+-V272-P335 POPOV VS-1982-ITEP101-PREPR POPOV VS-1984-ITEP119-PREPR PRIVMAN V-1981-PHYS-LETT-A-V81-P326 ROGERS FJ-1970-PHYS-REV-A-V1-P1577 SERGEEV AV-1982-ZH-EKSP-TEOR-FIZ+-V82-P1070 SILVERSTONE HJ-1978-PHYS-REV-A-V18-P1853 TURBINER AV-1980-ZH-EKSP-TEOR-FIZ+-V79-P1719 WEINBERG VM-1982-ITEP160-PREPR WEINBERG VM-1980-ITEP171-PREPR WEINBERG VM-1984-ITEP35-PREPR ZINNJUSTIN J-1981-PHYS-REP-V70-P109
Source item page count:	5
IDS No.:	ADX46
29-char source abbrev:	PHYS LETT A

Record 73 of 74
Author(s):	VAINBERG VM; POPOV VS
Title:	SUMMATION OF SERIES OF THE PERTURBATION-THEORY FOR YUKAWA POTENTIAL
Source:	DOKLADY AKADEMII NAUK SSSR 1983, Vol 272, Iss 2, pp 335-340
No. cited references:	16
Cited references:	ALLILUEV SP-1983-DAN-SSSR-V271 ALLILUEV SP-1982-DOKL-AKAD-NAUK-SSSR+-V265-P597 BAKER GA-1975-ESSENTIALS-PADE-APPR BOGOMOLNY E-1980-SOVIET-SCI-REV-A-V2-P247 ELETSKY VL-1981-PHYS-LETT-A-V84-P235 ELETSKY VL-1981-ZHETF-V81-P1567 KESARWANI RN-1978-J-MATH-PHYS-V19-P819 POPOV VS-1982-ITEP101-PREPR POPOV VS-1982-PHYS-LETT-A-V90-P107 PRIVMAN V-1981-PHYS-LETT-A-V81-P326 ROGERS FJ-1970-PHYS-REV-A-V1-P1577 SERGEEV AV-1982-ZH-EKSP-TEOR-FIZ+-V82-P1070 TRUBNIKOV BA-1965-ZHETF-V48-P1618 VAINBERG VM-1980-ITEF171-PREPR WEINBERG VM-1982-ITEP160-PREPR ZINNJUSTIN J-1981-PHYS-REP-V70-P109
Source item page count:	6
IDS No.:	RT573
29-char source abbrev:	DOKL AKAD NAUK SSSR

Record 74 of 74
Author(s):	ALLILUEV SP; POPOV VS
Title:	LOGARITHMIC PERTURBATION-THEORY FOR THE SCREENED COULOMB POTENTIAL
Source:	DOKLADY AKADEMII NAUK SSSR 1983, Vol 271, Iss 6, pp 1345-1348
No. cited references:	15
Addresses:	ALLILUEV SP, MOSCOW ENGN PHYS INST, MOSCOW, USSR.
Cited references:	ALLILUEV SP-1982-DOKL-AKAD-NAUK-SSSR+-V265-P597 DOLGOV AD-1979-PHYS-LETT-B-V86-P185 DOLGOV AD-1978-PHYS-LETT-B-V79-P403 DOLGOV AD-1978-ZH-EKSP-TEOR-FIZ+-V75-P2010 ELETSKY VL-1981-PHYS-LETT-A-V84-P235 ELETSKY VL-1981-ZHETF-V81-P1567 GRANT M-1979-PHYS-REV-A-V20-P718 IAFRATE GJ-1969-PHYS-REV-V182-P244 LAI CS-1980-PHYS-REV-A-V21-P1100 LANDAU LD-1963-KVANTOVAYA-MEKHANIKA POLIKANOV VS-1967-ZHETF-V52-P1326 PRIVMAN V-1981-PHYS-LETT-A-V81-P326 SERGEEV AV-1982-ZH-EKSP-TEOR-FIZ+-V82-P1070 TURBINER AV-1982-9YA-SHKOL-FIZ-ITEF-E-P39 VAINBERG VM-1980-ITEF171-PREPR
Source item page count:	4
IDS No.:	RL647
29-char source abbrev:	DOKL AKAD NAUK SSSR