Maximising and Stabilising Luminescence in Metal Halide Perovskite Device Structures

TL;DR

This paper demonstrates a method to significantly enhance luminescence efficiency and stability in metal halide perovskite devices by surface passivation, achieving high quantum yields and suppressing ion migration, crucial for high-performance optoelectronic applications.

Contribution

The study introduces potassium-halide interlayers to reduce non-radiative losses and ion migration, enabling high luminescence yields and stable bandgaps in perovskite devices, advancing their application potential.

Findings

External quantum yields of 66% achieved

High charge mobilities over 40 cm2V-1s-1 maintained

Suppression of photo-induced ion migration demonstrated

Abstract

Metal halide perovskites are attracting tremendous interest for a variety of optoelectronic applications. The ability to tune the perovskite bandgap by tweaking the chemical compositions opens up new applications as coloured emitters and as components of tandem photovoltaics. Nevertheless, non-radiative losses are still limiting performance, with luminescence yields in state-of-the-art perovskite solar cells still far from 100% under solar illumination conditions. Furthermore, in mixed halide perovskite systems designed for continuous bandgap tunability (bandgaps ~1.7-1.9 eV), photo-induced ion segregation leads to bandgap instabilities. Here, we substantially mitigate both non-radiative losses and photo-induced ion migration in perovskite structures by decorating the surfaces and grain boundaries with passivating potassium-halide interlayers. We demonstrate external photo-luminescence quantum yields of 66%, translating to internal yields exceeding 95%. The high luminescence yields are achieved while maintaining high mobilities over 40 cm2V-1s-1, giving the elusive combination of both high luminescence and excellent charge transport. We find that the external luminescence yield when interfaced with electrodes in a solar cell device stack, a quantity that must be maximized to approach the efficiency limits, remains as high as 15%, indicating very clean interfaces. We also demonstrate the inhibition of photo-induced ion migration processes across a wide range of mixed halide perovskite bandgaps that otherwise show bandgap instabilities. We validate these results in full operating solar cells, highlighting the importance of stabilising luminescence in device structures. Our work represents a critical breakthrough in the construction of tunable halide perovskite films and interfaces that can approach the efficiency limits in tandem solar cells and coloured LEDs.