TY - JOUR
T1 - Quantum chemistry with the Douglas-Kroll-Hess approach to relativistic density functional theory
T2 - Efficient methods for molecules and materials
AU - Rösch, Notker
AU - Matveev, Alexei
AU - Nasluzov, Vladimir A.
AU - Neyman, Konstantin M.
AU - Moskaleva, Lyudmila
AU - Krüger, Sven
N1 - Funding Information:
We thank G.A. Bowmaker, S. Cai, C. Di Valentin, M. Drees, A.M. Ferrari, M.S.K. Fuchs-Rohr, M. García-Hernández, J.F. Goellner, A. Hu, F. Illas, C. Lauterbach-Willnauer, S. Majumder, M. Mayer, G. Pacchioni, V.V. Rivanenkov, R. Sahnoun, F. Schlosser, A.M. Shor, α. Spörl, M. Stener, S. Vent, C. Xiao, and I.V. Yudanov for their contributions to the research reviewed here. The authors enjoyed collaborations with the experimentally working colleagues H.-J. Freund, B.C. Gates, J. Libuda, G. Rupprechter, and H. Schmidbaur. The members of the PARAGAUSS team T. Belling, T. Grauschopf, F. Nörtemann, M. Staufer, M. Mayer, U. Birkenheuer, A. Hu, A.M. Shor, M.S.K. Fuchs-Rohr, D.I. Ganyushin, T. Kerdcharoen, A. Woiterski, and A.B. Gordienko deserve particular recognition; they helped to develop an efficient computational tool with unique features. The research was supported by Deutsche Forschungsgemeinschaft (via SFB 338 and several Priority Programs), Alexander von Humboldt Foundation, Volkswagen-Stiftung, INTAS, Bundesministerium für Wirtschaft und Arbeit (contract 02E9450), and Fonds der Chemischen Industrie (Germany).
PY - 2004
Y1 - 2004
N2 - We review the Douglas-Kroll-Hess (DKH) approach to relativistic density functional calculations for molecular systems, also in comparison with other two-component approaches and four-component relativistic quantum chemistry methods. The scalar relativistic variant of the DKH method of solving the Dirac-Kohn-Sham problem is an efficient procedure for treating compounds of heavy elements including such complex systems as transition metal clusters, adsorption complexes, and solvated actinide compounds. This method allows routine all-electron density functional calculations on heavy-element compounds and provides a reliable alternative to the popular approximate strategy based on relativistic effective core potentials. We discuss recent method development aimed at an efficient treatment of spin-orbit interaction in the DKH approach as well as calculations of g tensors. Comparison with results of four-component methods for small molecules reveals that, for many application problems, a two-component treatment of spin-orbit interaction can be competitive with these more precise procedures.
AB - We review the Douglas-Kroll-Hess (DKH) approach to relativistic density functional calculations for molecular systems, also in comparison with other two-component approaches and four-component relativistic quantum chemistry methods. The scalar relativistic variant of the DKH method of solving the Dirac-Kohn-Sham problem is an efficient procedure for treating compounds of heavy elements including such complex systems as transition metal clusters, adsorption complexes, and solvated actinide compounds. This method allows routine all-electron density functional calculations on heavy-element compounds and provides a reliable alternative to the popular approximate strategy based on relativistic effective core potentials. We discuss recent method development aimed at an efficient treatment of spin-orbit interaction in the DKH approach as well as calculations of g tensors. Comparison with results of four-component methods for small molecules reveals that, for many application problems, a two-component treatment of spin-orbit interaction can be competitive with these more precise procedures.
UR - http://www.scopus.com/inward/record.url?scp=1542410198&partnerID=8YFLogxK
U2 - 10.1016/s1380-7323(04)80038-4
DO - 10.1016/s1380-7323(04)80038-4
M3 - Review article
AN - SCOPUS:1542410198
SN - 1380-7323
VL - 14
SP - 656
EP - 722
JO - Theoretical and Computational Chemistry
JF - Theoretical and Computational Chemistry
ER -