Guest-induced phase transition leads to polarization enhancement in MHyPbCl3

TL;DR

This study uses first-principles calculations to analyze how guest-host interactions in MHyPbCl3 cause a phase transition that unexpectedly enhances polarization with temperature, revealing new insights into the material's properties.

Contribution

It provides a detailed atomistic understanding of the guest-induced phase transition and polarization enhancement in MHyPbCl3, highlighting the dominant role of host atoms and guest feedback polarization.

Findings

Phase transition driven mainly by guest reorientation.

Polarization increases with temperature due to host distortion.

Host distortion significantly affects guest electronic states.

Abstract

We present a detailed first-principles investigation of the structural and polar properties of 3D hybrid perovskite, methylhydrazinium lead chloride, MHyPbCl3, as it transitions from a highly polar Phase-I (high temperature, HT) to less polar Phase-II (low temperature, LT) from the perspective of host/guest interactions. Structurally, the two phases vary in the orientation of the guest and the two differently distorted host layers. The transition character (TC) across the path of phase transition and a relatively high guest-reorientation barrier tells that the transition is primarily governed by guest-reorientation. This overall guest/host transition is interesting because it leads to enhancement in polarization with temperature which is quite unusual. Maximally localized Wannier functions (MLWFs) have been used to probe into the atomistic origin of this enhancement which establishes the leading role of the host atoms, especially those lying in the more distorted octahedral layer, with only a negligible contribution from the guest, despite the fact that it is the primary effect leading to transition. Furthermore, we also find a significant feedback polarization of ~9% that the host distortion induces on the guest. This has a direct effect on the density of states occupied by the guest, which shifts away from the band edge with the increase in the host distortion (for Phase-II guest orientation). Thus the organic cations in 3D perovskites can also have a non-trivial contribution to the optoelectronic properties and exciton binding energies.