Understanding Transient Photoluminescence in Halide Perovskite Layer Stacks and Solar Cells

TL;DR

This paper improves understanding of transient photoluminescence in halide perovskite layers and solar cells by combining simulations, analytical solutions, and experiments to interpret complex charge-carrier dynamics.

Contribution

It introduces a new method of analyzing the decay time of TPL to distinguish various recombination and charge transfer effects in multilayer perovskite samples.

Findings

Decay time analysis reveals contributions of radiative and non-radiative recombination.

Differentiates charge transfer effects from capacitive charging.

Applicable across various sample geometries from films to full devices.

Abstract

While transient photoluminescence measurements are a very popular tool to monitor the charge-carrier dynamics in the field of halide perovskite photovoltaics, interpretation of data obtained on multilayer samples is highly challenging due to the superposition of various effects that modulate the charge-carrier concentration in the perovskite layer and thereby the measured PL. These effects include bulk and interfacial recombination, charge transfer to electron or hole transport layers and capacitive charging or discharging. Here, numerical simulations with Sentauraus TCAD, analytical solutions and experimental data with a dynamic range of ~7 orders of magnitude on a variety of different sample geometries from perovskite films on glass to full devices are combined to present an improved understanding of this method. A presentation of the decay time of the TPL decay that follows from taking the derivative of the photoluminescence at every time is proposed. Plotting this decay time as a function of the time-dependent quasi-Fermi level splitting enables distinguishing between the different contributions of radiative and non-radiative recombination as well as charge extraction and capacitive effects to the decay.