Constrained Density Functional Theory: A Potential-Based Self-Consistency Approach
Permanent link
https://hdl.handle.net/10037/28273Date
2022-09-13Type
Journal articleTidsskriftartikkel
Peer reviewed
Author
Gonze, Xavier; Seddon, Benjamin; Elliott, James A.; Tantardini, Christian; Shapeev, Alexander V.Abstract
Chemical reactions, charge transfer reactions, and
magnetic materials are notoriously difficult to describe within
Kohn−Sham density functional theory, which is strictly a groundstate technique. However, over the last few decades, an
approximate method known as constrained density functional
theory (cDFT) has been developed to model low-lying excitations
linked to charge transfer or spin fluctuations. Nevertheless, despite
becoming very popular due to its versatility, low computational
cost, and availability in numerous software applications, none of the
previous cDFT implementations is strictly similar to the
corresponding ground-state self-consistent density functional
theory: the target value of constraints (e.g., local magnetization)
is not treated equivalently with atomic positions or lattice
parameters. In the present work, by considering a potential-based formulation of the self-consistency problem, the cDFT is
recast in the same framework as Kohn−Sham DFT: a new functional of the potential that includes the constraints is proposed, where
the constraints, the atomic positions, or the lattice parameters are treated all alike, while all other ingredients of the usual potentialbased DFT algorithms are unchanged, thanks to the formulation of the adequate residual. Tests of this approach for the case of spin
constraints (collinear and noncollinear) and charge constraints are performed. Expressions for the derivatives with respect to
constraints (e.g., the spin torque) for the atomic forces and the stress tensor in cDFT are provided. The latter allows one to study
striction effects as a function of the angle between spins. We apply this formalism to body-centered cubic iron and first reproduce the
well-known magnetization amplitude as a function of the angle between local magnetizations. We also study stress as a function of
such an angle. Then, the local collinear magnetization and the local atomic charge are varied together. Since the atomic spin
magnetizations, local atomic charges, atomic positions, and lattice parameters are treated on an equal footing, this formalism is an
ideal starting point for the generation of model Hamiltonians and machine-learning potentials, computation of second or third
derivatives of the energy as delivered from density-functional perturbation theory, or for second-principles approaches.
Publisher
American chemical societyCitation
Gonze, Seddon, Elliott, Tantardini, Shapeev. Constrained Density Functional Theory: A Potential-Based Self-Consistency Approach. Journal of Chemical Theory and Computation. 2022;18(10):6099-6110Metadata
Show full item recordCollections
Copyright 2022 The Author(s)