Volume 254, 2024

Challenges with relativistic GW calculations in solids and molecules

Abstract

For molecules and solids containing heavy elements, accurate electronic-structure calculations require accounting not only for electronic correlations but also for relativistic effects. In molecules, relativity can lead to severe changes in the ground-state description. In solids, the interplay between both correlation and relativity can change the stability of phases or it can lead to an emergence of completely new phases. Traditionally, the simplest illustration of relativistic effects can be done either by including pseudopotentials in non-relativistic calculations or alternatively by employing large all-electron basis sets in relativistic methods. By analyzing different electronic properties (band structure, equilibrium lattice constant and bulk modulus) in semiconductors and insulators, we show that capturing the interplay of relativity and electron correlation can be rather challenging in Green's function methods. For molecular problems with heavy elements, we also observe that similar problems persist. We trace these challenges to three major problems: deficiencies in pseudopotential treatment as applied to Green's function methods, the scarcity of accurate and compact all-electron basis sets that can be converged with respect to the basis-set size, and linear dependencies arising in all-electron basis sets, particularly when employing Gaussian orbitals. Our analysis provides detailed insight into these problems and opens a discussion about potential approaches to mitigate them.

Graphical abstract: Challenges with relativistic GW calculations in solids and molecules

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Article information

Article type
Paper
Submitted
29 2 2024
Accepted
04 3 2024
First published
20 3 2024
This article is Open Access
Creative Commons BY license

Faraday Discuss., 2024,254, 216-238

Challenges with relativistic GW calculations in solids and molecules

G. Harsha, V. Abraham and D. Zgid, Faraday Discuss., 2024, 254, 216 DOI: 10.1039/D4FD00043A

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