Variations on the “exact factorization” theme

In a series of publications, Hardy Gross and co-workers have highlighted the interest of an “exact factorization” approach to the interacting electron-nuclei problem, be it time-independent or time-dependent. In this approach, an effective potential governs the dynamics of the nuclei such that the r...

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Bibliographic Details
Published inThe European physical journal. B, Condensed matter physics Vol. 91; no. 10
Main Authors Gonze, Xavier, Zhou, Jianqiang Sky, Reining, Lucia
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 01.10.2018
Springer
Springer Nature B.V
Springer-Verlag
Subjects
Analysis
Boson fields
Bosons
Complex Systems
Condensed Matter
Condensed Matter Physics
Density
Electrons
Factorization
Fluid- and Aerodynamics
Mathematical models
Nuclei (nuclear physics)
Other
Physics
Physics and Astronomy
Regular Article
Solid State Physics
Time dependence
Topical issue: Special issue in honor of Hardy Gross
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Summary:In a series of publications, Hardy Gross and co-workers have highlighted the interest of an “exact factorization” approach to the interacting electron-nuclei problem, be it time-independent or time-dependent. In this approach, an effective potential governs the dynamics of the nuclei such that the resulting N -body nuclear density is in principle exact. This contrasts with the more usual adiabatic approach, where the effective potential leads to an approximate nuclear density. Inspired by discussions with Hardy, we explore the factorization idea for arbitrary many-body Hamiltonians, generalizing the electron-nuclei case, with a focus on the static case. While the exact equations do not lead to any practical advantage, they are illuminating, and may therefore constitute a suitable starting point for approximations. In particular, we find that unitary transformations that diagonalize the coupling term for one of the sub-systems make exact factorization appealing. The algorithms by which the equations for the separate subsystems can be solved in the time-independent case are also explored. We illustrate our discussions using the two-site Holstein model and the quantum Rabi model. Two factorization schemes are possible: one where the boson field feels a potential determined by the electrons, and the reverse exact factorization, where the electrons feel a potential determined by the bosons; both are explored in this work. A comparison with a self-energy approach is also presented.
ISSN:1434-6028
1434-6036
DOI:10.1140/epjb/e2018-90278-2