# Towards predictive band gaps for halide perovskites: Lessons from   one-shot and eigenvalue self-consistent GW

**Authors:** Linn Leppert, Tonatiuh Rangel, Jeffrey B. Neaton

arXiv: 1903.11376 · 2019-10-23

## TL;DR

This study evaluates computational methods for accurately predicting the band gaps of diverse halide perovskites, highlighting the importance of hybrid functional starting points in GW calculations for systems with strong spin-orbit coupling.

## Contribution

It demonstrates that GW calculations with hybrid functional starting points improve band gap predictions for halide perovskites with complex electronic structures.

## Key findings

- Standard GGA underestimates experimental band gaps.
- Eigenvalue self-consistent GW0 inherits DFT inaccuracies.
- Hybrid functional-based GW0 yields better agreement with experiments.

## Abstract

Halide perovskites constitute a chemically-diverse class of crystals with great promise as photovoltaic absorber materials, featuring band gaps between about 1 and 3.5 eV depending on composition. Their diversity calls for a general computational approach to predicting their band gaps. However, such an approach is still lacking. Here, we use density functional theory (DFT) and many-body perturbation theory within the GW approximation to compute the quasiparticle or fundamental band gap of a set of ten representative halide perovskites: CH$_3$NH$_3$PbI$_3$ (MAPbI$_3$), MAPbBr$_3$, CsSnBr$_3$, (MA)$_2$BiTlBr$_6$, Cs$_2$TlAgBr$_6$, Cs$_2$TlAgCl$_6$, Cs$_2$BiAgBr$_6$, Cs$_2$InAgCl$_6$, Cs$_2$SnBr$_6$, and Cs$_2$Au$_2$I$_6$. Comparing with recent measurements, we find that a standard generalized gradient exchange-correlation functional can significantly underestimate the experimental band gaps of these perovskites, particularly in cases with strong spin-orbit coupling (SOC) and highly dispersive band edges, to a degree that varies with composition. We show that these nonsystematic errors are inherited by one-shot G$_0$W$_0$ and eigenvalue self-consistent GW$_0$ calculations, demonstrating that semilocal DFT starting points are insufficient for MAPbI$_3$, MAPbBr$_3$, CsSnBr$_3$, (MA)$_2$BiTlBr$_6$, Cs$_2$TlAgBr$_6$, and Cs$_2$TlAgCl$_6$. On the other hand, we find that DFT with hybrid functionals leads to an improved starting point and GW$_0$ results in better agreement with experiment for these perovskites. Our results suggest that GW$_0$ with hybrid functional-based starting points are promising for predicting band gaps of systems with large SOC and dispersive bands in this technologically important class of semiconducting crystals.

## Full text

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## Figures

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## References

76 references — full list in the complete paper: https://tomesphere.com/paper/1903.11376/full.md

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Source: https://tomesphere.com/paper/1903.11376