Superconductivity, generalized random phase approximation and linear scaling methods

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Journal Title
Journal ISSN
Volume Title
A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä
Date
2022-11-01
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Mcode
Degree programme
Language
en
Pages
17
1-17
Series
New Journal of Physics, Volume 24, issue 11
Abstract
The superfluid weight is an important observable of superconducting materials since it is related to the London penetration depth of the Meissner effect. It can be computed from the change in the grand potential (or free energy) in response to twisted boundary conditions in a torus geometry. Here we review the Bardeen-Cooper-Schrieffer mean-field theory emphasizing its origin as a variational approximation for the grand potential. The variational parameters are the effective fields that enter in the mean-field Hamiltonian, namely the Hartree-Fock potential and the pairing potential. The superfluid weight is usually computed by ignoring the dependence of the effective fields on the twisted boundary conditions. However, it has been pointed out in recent works that this can lead to unphysical results, particularly in the case of lattice models with flat bands. As a first result, we show that taking into account the dependence of the effective fields on the twisted boundary conditions leads in fact to the generalized random phase approximation. Our second result is providing the mean-field grand potential as an explicit function of the one-particle density matrix. This allows us to derive the expression for the superfluid weight within the generalized random phase approximation in a transparent manner. Moreover, reformulating mean-field theory as a well-posed minimization problem in terms of the one-particle density matrix is a first step towards the application to superconducting systems of the linear scaling methods developed in the context of electronic structure theory.
Description
Funding Information: We thank Koushik Swaminathan, Pham Nguyen Minh, Riku Tuovinen, Ville Pyykkönen, Jami Kinnunen, Kukka-Emilia Huhtinen, Päivi Törmä and Giovanni Vignale for useful discussions and proofreading. This work has been supported by the Academy of Finland under Grant Nos. 330384 and 336369.
Keywords
density matrix, disorder, generalized random phase approximation, linear scaling, mean-field theory, superconductivity, superfluid weight
Other note
Citation
Peotta, S 2022, ' Superconductivity, generalized random phase approximation and linear scaling methods ', New Journal of Physics, vol. 24, no. 11, 113019, pp. 1-17 . https://doi.org/10.1088/1367-2630/ac9d5c