In:
International Journal of Quantum Chemistry, Wiley, Vol. 120, No. 21 ( 2020-11)
Abstract:
This perspective considers two theories we recently proposed to perform quantum embedding calculations for chemical systems: domain‐separated density functional theory (DS‐DFT) and locally coupled open subsystems (LCOS). The development includes both the fundamentals of each theory as well as potential applications, some technical aspects, and related challenges. DS‐DFT is suited to study intramolecular effects, where one can apply a high level of theory (based on DFT or wave function theory) to a region of interest inside a molecule or solid and lower level theory elsewhere, with smooth switching between the regions. LCOS, in contrast, is a fragment‐based embedding, which offers computational advantages to study intermolecular behavior such as electron hopping, spin‐environment interaction, and charge‐transfer excitations. However, both theories can exchange roles when appropriate. In addition, these theories allow for control of computational scaling of their algorithms. We explore paths to determine the charge‐transfer operator used in LCOS, and suggest an auxiliary energy minimization that can provide a practical estimate to this operator. We also briefly discuss how to implement density fitting techniques in domain separation, and how domain separation can be used for pure wave function‐based embedding.
Type of Medium:
Online Resource
ISSN:
0020-7608
,
1097-461X
Language:
English
Publisher:
Wiley
Publication Date:
2020
detail.hit.zdb_id:
1475014-4
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