Surface hopping, electron translation factors, electron rotation factors, momentum conservation, and size consistency

Author:

Athavale Vishikh1ORCID,Bian Xuezhi1ORCID,Tao Zhen1ORCID,Wu Yanze1ORCID,Qiu Tian1ORCID,Rawlinson Jonathan2ORCID,Littlejohn Robert G.3ORCID,Subotnik Joseph E.1ORCID

Affiliation:

1. Department of Chemistry, University of Pennsylvania 1 , Philadelphia, Pennsylvania 19104, USA

2. Department of Mathematics, University of Manchester 2 , Manchester M13 9PL, United Kingdom

3. Department of Physics, University of California 3 , Berkeley, California 94720, USA

Abstract

For a system without spin–orbit coupling, the (i) nuclear plus electronic linear momentum and (ii) nuclear plus orbital electronic angular momentum are good quantum numbers. Thus, when a molecular system undergoes a nonadiabatic transition, there should be no change in the total linear or angular momentum. Now, the standard surface hopping algorithm ignores the electronic momentum and indirectly equates the momentum of the nuclear degrees of freedom to the total momentum. However, even with this simplification, the algorithm still does not conserve either the nuclear linear or the nuclear angular momenta. Here, we show that one way to address these failures is to dress the derivative couplings (i.e., the hopping directions) in two ways: (i) we disallow changes in the nuclear linear momentum by working in a translating basis (which is well known and leads to electron translation factors) and (ii) we disallow changes in the nuclear angular momentum by working in a basis that rotates around the center of mass [which is not well-known and leads to a novel, rotationally removable component of the derivative coupling that we will call electron rotation factors below, cf. Eq. (96)]. The present findings should be helpful in the short term as far as interpreting surface hopping calculations for singlet systems (without spin) and then developing the new surface hopping algorithm in the long term for systems where one cannot ignore the electronic orbital and/or spin angular momentum.

Funder

National Science Foundation

Publisher

AIP Publishing

Subject

Physical and Theoretical Chemistry,General Physics and Astronomy

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