Your search keyword '"Rigter, Susan A."' showing total 2 results

1. Spectroscopic Analysis for the Identification of Loss Mechanisms in Back-Contact Perovskite Solar Cells

Author

Sun, Hongyu, Gillespie, Sarah, Rigter, Susan A., van der Burgt, Julia S., Datta, Kunal, Garnett, Erik C., Sun, Hongyu, Gillespie, Sarah, Rigter, Susan A., van der Burgt, Julia S., Datta, Kunal, and Garnett, Erik C.

Abstract

Back-contact perovskite solar cells offer a significant potential to reach high efficiency due to reduced parasitic absorption from the top surface. However, the currently reported efficiencies are considerably lower (<10%) than planar perovskite solar cells (>20%). Herein, back-contact perovskite solar cells are fabricated to study loss mechanisms that cause low device efficiency. This work spatially resolves the short-circuit current, open-circuit voltage, photoluminescence quantum yield, carrier lifetime, and external quantum efficiency of the devices. The results indicate that the front surface recombination, increased nonradiative recombination at hole contact layer/perovskite interface, and the extraction barriers are three main mechanisms limiting devices from achieving high efficiencies.

Published

2023

2. Passivation Properties and Formation Mechanism of Amorphous Halide Perovskite Thin Films

Author

Rigter, Susan A., Quinn, Xueying L., Kumar, Rishi E., Fenning, David P., Massonnet, Philippe, Ellis, Shane R., Heeren, Ron M. A., Svane, Katrine Louise, Walsh, Aron, Garnett, Erik C., Rigter, Susan A., Quinn, Xueying L., Kumar, Rishi E., Fenning, David P., Massonnet, Philippe, Ellis, Shane R., Heeren, Ron M. A., Svane, Katrine Louise, Walsh, Aron, and Garnett, Erik C.

Abstract

Lead halide perovskites are among the most exciting classes of optoelectronic materials due to their unique ability to form high‐quality crystals with tunable bandgaps in the visible and near‐infrared using simple solution precipitation reactions. This facile crystallization is driven by their ionic nature; just as with other salts, it is challenging to form amorphous halide perovskites, particularly in thin‐film form where they can most easily be studied. Here, rapid desolvation promoted by the addition of acetate precursors is shown as a general method for making amorphous lead halide perovskite films with a wide variety of compositions, including those using common organic cations (methylammonium and formamidinium) and anions (bromide and iodide). By controlling the amount of acetate, it is possible to tune from fully crystalline to fully amorphous films, with an interesting intermediate state consisting of crystalline islands embedded in an amorphous matrix. The amorphous lead halide perovskite has a large and tunable optical bandgap. It improves the photoluminescence quantum yield and lifetime of incorporated crystalline perovskite, opening up the intriguing possibility of using amorphous perovskite as a passivating contact, as is currently done in record efficiency silicon solar cells.

Published

2021