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GENERALIZED RECPACCOUNTING FOR BREIT EFFECTS : URANIUM, PLUTONIUM AND SUPERHEAVY ELEMENTS 112, 113, 114. / Mosyagin, N. S.; Petrov, A. N.; Titov, A. V.; Tupitsyn, I. I.

Progress in Theoretical Chemistry and Physics. Springer Nature, 2006. p. 229-251 (Progress in Theoretical Chemistry and Physics; Vol. 15).

Research output: Chapter in Book/Report/Conference proceedingChapterResearchpeer-review

Harvard

Mosyagin, NS, Petrov, AN, Titov, AV & Tupitsyn, II 2006, GENERALIZED RECPACCOUNTING FOR BREIT EFFECTS: URANIUM, PLUTONIUM AND SUPERHEAVY ELEMENTS 112, 113, 114. in Progress in Theoretical Chemistry and Physics. Progress in Theoretical Chemistry and Physics, vol. 15, Springer Nature, pp. 229-251. https://doi.org/10.1007/1-4020-4528-X_11

APA

Mosyagin, N. S., Petrov, A. N., Titov, A. V., & Tupitsyn, I. I. (2006). GENERALIZED RECPACCOUNTING FOR BREIT EFFECTS: URANIUM, PLUTONIUM AND SUPERHEAVY ELEMENTS 112, 113, 114. In Progress in Theoretical Chemistry and Physics (pp. 229-251). (Progress in Theoretical Chemistry and Physics; Vol. 15). Springer Nature. https://doi.org/10.1007/1-4020-4528-X_11

Vancouver

Mosyagin NS, Petrov AN, Titov AV, Tupitsyn II. GENERALIZED RECPACCOUNTING FOR BREIT EFFECTS: URANIUM, PLUTONIUM AND SUPERHEAVY ELEMENTS 112, 113, 114. In Progress in Theoretical Chemistry and Physics. Springer Nature. 2006. p. 229-251. (Progress in Theoretical Chemistry and Physics). https://doi.org/10.1007/1-4020-4528-X_11

Author

Mosyagin, N. S. ; Petrov, A. N. ; Titov, A. V. ; Tupitsyn, I. I. / GENERALIZED RECPACCOUNTING FOR BREIT EFFECTS : URANIUM, PLUTONIUM AND SUPERHEAVY ELEMENTS 112, 113, 114. Progress in Theoretical Chemistry and Physics. Springer Nature, 2006. pp. 229-251 (Progress in Theoretical Chemistry and Physics).

BibTeX

@inbook{a4d525d5cad94a72af0bfa7c0175c718,
title = "GENERALIZED RECPACCOUNTING FOR BREIT EFFECTS: URANIUM, PLUTONIUM AND SUPERHEAVY ELEMENTS 112, 113, 114",
abstract = "The Generalized Relativistic Effective Core Potential (GRECP) method is described, which allows to simulate Breit interaction and finite nuclear models by an economic way with high accuracy. The corresponding GRECPs for the uranium, plutonium, eka-mercury (E112), eka-thallium (E113) and eka-lead (E114) atoms are generated. The accuracy of these GRECPs and of the RECPs of other groups is estimated in atomic numerical SCF calculations with Coulomb two-electron interactions and point nucleus as compared to the corresponding all-electron Hartree-Fock-Dirac- Breit calculations with the Fermi nuclear charge distribution. Different nuclear models and contributions of the Breit interaction between different shells are studied employing all-electron four-component methods.",
keywords = "Core Electron, Inner Core, Nuclear Charge, Outer Core, Transition Energy",
author = "Mosyagin, {N. S.} and Petrov, {A. N.} and Titov, {A. V.} and Tupitsyn, {I. I.}",
note = "Publisher Copyright: {\textcopyright} 2006, Springer.",
year = "2006",
doi = "10.1007/1-4020-4528-X_11",
language = "English",
series = "Progress in Theoretical Chemistry and Physics",
publisher = "Springer Nature",
pages = "229--251",
booktitle = "Progress in Theoretical Chemistry and Physics",
address = "Germany",

}

RIS

TY - CHAP

T1 - GENERALIZED RECPACCOUNTING FOR BREIT EFFECTS

T2 - URANIUM, PLUTONIUM AND SUPERHEAVY ELEMENTS 112, 113, 114

AU - Mosyagin, N. S.

AU - Petrov, A. N.

AU - Titov, A. V.

AU - Tupitsyn, I. I.

N1 - Publisher Copyright: © 2006, Springer.

PY - 2006

Y1 - 2006

N2 - The Generalized Relativistic Effective Core Potential (GRECP) method is described, which allows to simulate Breit interaction and finite nuclear models by an economic way with high accuracy. The corresponding GRECPs for the uranium, plutonium, eka-mercury (E112), eka-thallium (E113) and eka-lead (E114) atoms are generated. The accuracy of these GRECPs and of the RECPs of other groups is estimated in atomic numerical SCF calculations with Coulomb two-electron interactions and point nucleus as compared to the corresponding all-electron Hartree-Fock-Dirac- Breit calculations with the Fermi nuclear charge distribution. Different nuclear models and contributions of the Breit interaction between different shells are studied employing all-electron four-component methods.

AB - The Generalized Relativistic Effective Core Potential (GRECP) method is described, which allows to simulate Breit interaction and finite nuclear models by an economic way with high accuracy. The corresponding GRECPs for the uranium, plutonium, eka-mercury (E112), eka-thallium (E113) and eka-lead (E114) atoms are generated. The accuracy of these GRECPs and of the RECPs of other groups is estimated in atomic numerical SCF calculations with Coulomb two-electron interactions and point nucleus as compared to the corresponding all-electron Hartree-Fock-Dirac- Breit calculations with the Fermi nuclear charge distribution. Different nuclear models and contributions of the Breit interaction between different shells are studied employing all-electron four-component methods.

KW - Core Electron

KW - Inner Core

KW - Nuclear Charge

KW - Outer Core

KW - Transition Energy

UR - http://www.scopus.com/inward/record.url?scp=33846380793&partnerID=8YFLogxK

U2 - 10.1007/1-4020-4528-X_11

DO - 10.1007/1-4020-4528-X_11

M3 - Chapter

AN - SCOPUS:33846380793

T3 - Progress in Theoretical Chemistry and Physics

SP - 229

EP - 251

BT - Progress in Theoretical Chemistry and Physics

PB - Springer Nature

ER -

ID: 95300086