Atomistic mechanism for trapped-charge driven degradation of perovskite solar cells

TL;DR

This study uncovers the atomistic mechanisms behind the irreversible degradation of perovskite solar cells caused by trapped charges, oxygen, and water, revealing different pathways and proposing more stable material compositions.

Contribution

The paper combines experimental results and ab initio molecular dynamics simulations to identify trapped charges as the primary cause of perovskite degradation and details the degradation pathways at the atomic level.

Findings

Trapped charges induce oxygen- and moisture-related degradation pathways.

Deprotonation of organic cations occurs with trapped anionic charges and water.

A multi-component perovskite shows longer lifespan under light and oxygen.

Abstract

It is unmistakably paradoxical that the weakest point of the photoactive organic-inorganic hybrid perovskite is its instability against light. Why and how perovskites break down under light irradiation and what happens at the atomistic level during the degradation still remains unanswered. In this paper, we revealed the fundamental origin and mechanism for irreversible degradation of hybrid perovskite materials from our new experimental results and ab initio molecular dynamics (AIMD) simulations. We found that the photo-generated charges trapped along the grain boundaries of the perovskite crystal result in oxygen-induced irreversible degradation in air even in the absence of moisture. The present result, together with our previous experimental finding on the same critical role of trapped charges in the perovskite degradation under moisture, suggests that the trapped charges are the main culprit in both the oxygen- and moisture-induced degradation of perovskite materials. More detailed roles of oxygen and water molecules were investigated by tracking the atomic motions of the oxygen- or water-covered CH3NH3PbI3(MAPbI3) perovskite crystal surface with trapped charges via AIMD simulation. In the first few picoseconds of our simulation, trapped charges start disrupting the crystal structure, leading to a close-range interaction between oxygen or water molecules and the compositional ions of MAPbI3. We found that there are different degradation pathways depending on both the polarity of the trapped charge and the kind of gas molecule. Especially, the deprotonation of organic cations was theoretically predicted for the first time in the presence of trapped anionic charges and water molecules. We confirmed that a more structurally stable, multi-component perovskite material(MA0.6FA0.4PbI2.9Br0.1) exhibited a much longer lifespan than MAPbI3 under light irradiation even in 100% oxygen ambience.