Abstract
The development of novel materials for vacuum electron sources in particle accelerators is an active field of research that can greatly benefit from the results of ab initio calculations for the characterization of the electronic structure of target systems. As state-of-the-art many-body perturbation theory calculations are too expensive for large-scale material screening, density functional theory offers the best compromise between accuracy and computational feasibility. The quality of the obtained results, however, crucially depends on the choice of the exchange–correlation potential, v xc. To address this essential point, we systematically analyze the performance of three popular approximations of v xc [PBE, strongly constrained and appropriately normed (SCAN), and HSE06] on the structural and electronic properties of bulk Cs3Sb and Cs2Te as representative materials of Cs-based semiconductors employed in photocathode applications. Among the adopted approximations, PBE shows expectedly the largest discrepancies from the target: the unit cell volume is overestimated compared to the experimental value, while the band gap is severely underestimated. On the other hand, both SCAN and HSE06 perform remarkably well in reproducing both structural and electronic properties. Spin–orbit coupling, which mainly impacts the valence region of both materials inducing a band splitting and, consequently, a band-gap reduction of the order of 0.2 eV, is equally captured by all functionals. Our results indicate SCAN as the best trade-off between accuracy and computational costs, outperforming the considerably more expensive HSE06.
Highlights
Computational methods for material modelling have reached into almost all the areas of materials science and discovery, including those fields that, for historical reasons and scientific distance, are far away from condensed-matter physics
Recent studies on Cs-based multi-alkali antimonide crystals based on many-body perturbation theory (MBPT) provide state-of-the-art references for the electronic and optical characteristics of these materials [24, 25]
We studied the performance of different levels of approximations for the exchange-correlation potential (PBE, strongly constrained and appropriately normed (SCAN), and HSE06) in density functional theory (DFT) calculations on cesium antimonide and cesium telluride, both being actively used as photocathode materials for vacuum electron sources
Summary
Computational methods for material modelling have reached into almost all the areas of materials science and discovery, including those fields that, for historical reasons and scientific distance, are far away from condensed-matter physics. Recent studies on Cs-based multi-alkali antimonide crystals based on many-body perturbation theory (MBPT) provide state-of-the-art references for the electronic and optical characteristics of these materials [24, 25] These methods are too expensive to be used for high-throughput screening, or in the simulations of surfaces and defected systems, which more closely reflect the intrinsic features of the real materials at significantly large computational costs and complexity. Having the practical application in mind, we settled to consider functionals that are implemented and “ready to use” in a large number of DFT programs, and represent different levels of exchange-correlation approximations To this end, we choose three well-established functionals representative for increasing levels of sophistication in the treatment of the exchange-correlation potential, namely, the semi-local Perdew-Burke-Ernzerhof functional [48] implementing the generalized gradient approximation (GGA), the strongly constrained and appropriately normed (SCAN) parameterization of the meta-GGA [49], and the Heyd-Scuseria-Ernzerhof rangeseparated hybrid functional HSE06 [50].
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