Second-harmonic Generation Tensors from High-throughput Density-functional Perturbation Theory

Overview

Journal Sci Data

Specialty Science

Date 2024 Jul 11

PMID 38992023

Authors

Victor Trinquet

Francesco Naccarato

Guillaume Brunin

Guido Petretto

Ludger Wirtz

Geoffroy Hautier

Gian-Marco Rignanese

Affiliations

Soon will be listed here.

Abstract

Optical materials play a key role in enabling modern optoelectronic technologies in a wide variety of domains such as the medical or the energy sector. Among them, nonlinear optical crystals are of primary importance to achieve a broader range of electromagnetic waves in the devices. However, numerous and contradicting requirements significantly limit the discovery of new potential candidates, which, in turn, hinders the technological development. In the present work, the static nonlinear susceptibility and dielectric tensor are computed via density-functional perturbation theory for a set of 579 inorganic semiconductors. The computational methodology is discussed and the provided database is described with respect to both its data distribution and its format. Several comparisons with both experimental and ab initio results from literature allow to confirm the reliability of our data. The aim of this work is to provide a relevant dataset to foster the identification of promising nonlinear optical crystals in order to motivate their subsequent experimental investigation.

Citing Articles

Second-harmonic generation tensors from high-throughput density-functional perturbation theory.

Trinquet V, Naccarato F, Brunin G, Petretto G, Wirtz L, Hautier G Sci Data. 2024; 11(1):757.

PMID: 38992023 PMC: 11239842. DOI: 10.1038/s41597-024-03590-9.

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