# Orbital Engineering in Three Dimensional Halide Perovskites towards Two   Dimensional Properties with Strong Anisotropy

**Authors:** Gang Tang, Zewen Xiao, Jiawang Hong

arXiv: 1907.09879 · 2019-10-15

## TL;DR

This paper introduces an orbital engineering approach to induce two-dimensional electronic properties with strong anisotropy in three-dimensional halide perovskites by controlling d orbital hybridization, demonstrated through first-principles calculations.

## Contribution

It presents a novel strategy to achieve 2D electronic structures in 3D halide perovskites by manipulating d orbital hybridization, expanding the design space for electronic materials.

## Key findings

- Achieved flat conduction and valence bands via d orbital hybridization.
- Predicted highly anisotropic carrier mobilities in Cs2Au(I)Au(III)I6.
- Discovered excellent mechanical flexibility and ultra-small shear modulus.

## Abstract

The discovery of double perovskites A2B(I)B(III)X6 (A=monovalent cation; B(I)/B(III) = metal cation; X = halogen) as Pb(II)-free alternatives has attracted widespread attention, making it possible to introduce d-block metal cations (e.g., d0 and d10) into halide perovskites. However, at present, there are quite limited insights into the underlying bonding orbitals for d-block metal cation-based halide perovskites. Here, we present an orbital engineering strategy to construct two-dimensional (2D) electronic structures in three-dimensional (3D) halide perovskites by rationally controlling the d orbitals of the metal cations to hybridize with the halide p orbitals. Taking Cs2Au(I)Au(III)I6 as an example, we demonstrate that the flat conduction band and valence band at the band edges can be achieved simultaneously by combining two metal cations with different d orbital configurations using the first-principles calculations. The predicted carrier mobilities show huge anisotropy along the in-plane and out-of-plane directions in Cs2Au(I)Au(III)I6, further confirming the 2D electronic properties. In addition, the anisotropic static dielectronic constants and Young's modulus are also observed. More importantly, it is found that Cs2Au(I)Au(III)I6 has excellent mechanical flexible and an ultra-small shear modulus among halide perovskites. Our work provides valuable guidance for achieving low-dimensional electronic characteristic in three-dimensional halide perovskites for novel electronic applications.

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Source: https://tomesphere.com/paper/1907.09879