# Quasiparticle Levels at Large Interface Systems from Many-body   Perturbation Theory: the XAF-GW method

**Authors:** Fengyuan Xuan, Yifeng Chen, Su Ying Quek

arXiv: 1903.01847 · 2020-12-08

## TL;DR

The paper introduces XAF-GW, an efficient ab initio method for calculating quasiparticle levels in large interface systems, validated on various layered materials, significantly reducing computational costs while maintaining accuracy.

## Contribution

XAF-GW is a novel approach that simplifies quasiparticle calculations for large interfaces by assuming additive polarizability, validated for hybridized systems, and applicable to diverse dimensionalities.

## Key findings

- XAF-GW achieves results similar to full GW calculations for bilayer black phosphorus.
- The method reduces computational time and memory by expanding chi matrices from smaller sub-unit cells.
- Good agreement with experimental data for PTCDA monolayers on various substrates.

## Abstract

We present a fully ab initio approach based on many-body perturbation theory in the GW approximation, to compute the quasiparticle levels of large interface systems without significant covalent interactions between the different components of the interface. The only assumption in our approach is that the polarizability matrix (chi) of the interface can be given by the sum of the polarizability matrices of individual components of the interface. We show analytically, using a two-state hybridized model, that this assumption is valid even in the presence of interface hybridization to form bonding and anti-bonding states, up to first order in the overlap matrix elements involved in the hybridization. We validate our approach by showing that the band structure obtained in our method is almost identical to that obtained using a regular GW calculation for bilayer black phosphorus, where interlayer hybridization is significant. Significant savings in computational time and memory are obtained by computing chi only for the smallest sub-unit cell of each component, and expanding (unfolding) the chi matrix to that in the unit cell of the interface. To treat interface hybridization, the full wavefunctions of the interface are used in computing the self-energy. We thus call the method XAF-GW (X: eXpand-chi, A: Add-chi, F: Full wavefunctions). Compared to GW-embedding type approaches in the literature, the XAF-GW approach is not limited to specific screening environments or to non-hybridized interface systems. XAF-GW can also be applied to systems with different dimensionalities, as well as to Moire superlattices such as in twisted bilayers. We illustrate the generality and usefulness of our approach by applying it to self-assembled PTCDA monolayers on Au(111) and Ag(111), and PTCDA monolayers on graphite-supported monolayer WSe2, where good agreement with experiment is obtained.

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Source: https://tomesphere.com/paper/1903.01847