Efficiency limits of Perovskite Solar Cells with Transition Metal Oxides as Hole Transport Layers

TL;DR

This paper investigates the efficiency limits and stability challenges of perovskite solar cells using transition metal oxides as hole transport layers through detailed numerical simulations.

Contribution

It provides a comprehensive analysis of how ion migration impacts the performance and stability of TMO-based perovskite solar cells, highlighting their lower efficiency limits.

Findings

Ion migration is more detrimental in TMO-based cells with lower efficiency limits.

TMO contact layers lead to different hole collection mechanisms compared to other materials.

Efficiency limit for TMO-based cells is around 21% under certain conditions.

Abstract

Transition metal oxides (TMOs) like MoOx are increasingly explored as hole transport layers for perovskite-based solar cells. Due to their large work function, the hole collection mechanism of such solar cells are fundamentally different from other materials like PEDOT: PSS, and the associated device optimizations are not well elucidated. In addition, the prospects of such architectures against the challenges posed by ion migration are yet to be explored - which we critically examine in this contribution through detailed numerical simulations. Curiously, we find that, for similar ion densities and interface recombination velocities, ion migration is more detrimental for Perovskite solar cells with TMO contact layers with much lower achievable efficiency limits (21%). The insights shared by this work should be of broad interest to the community in terms of long-term stability, efficiency degradation and hence could help critically evaluate the promises and prospects of TMOs as hole contact layers for perovskite solar cells.