Adjusting Interfacial Chemistry and Electronic Properties of Photovoltaics Based on a Highly Pure Sb2S3 Absorber by Atomic Layer Deposition

The combination of oxide and heavier chalcogenide layers in thin film photovoltaics suffers limitations associated with oxygen incorporation and sulfur deficiency in the chalcogenide layer or with a chemical incompatibility which results in dewetting issues and defect states at the interface. Here, we establish atomic layer deposition (ALD) as a tool to overcome these limitations. ALD allows one to obtain highly pure Sb₂S₃ light absorber layers, and we exploit this technique to generate an additional interfacial layer consisting of 1.5 nm ZnS. This ultrathin layer simultaneously resolves dewetting and passivates defect states at the interface. We demonstrate via transient absorption spectroscopy that interfacial electron recombination is one order of magnitude slower at the ZnS-engineered interface than hole recombination at the Sb₂S₃/P3HT interface. The comparison of solar cells with and without oxide incorporation in Sb₂S₃, with and without the ultrathin ZnS interlayer, and with systematically varied Sb₂S₃ thickness provides a complete picture of the physical processes at work in the devices.

Partial oxidation of the absorber layer reduces charge carrier recombination in antimony sulfide solar cells

A controlled heat treatment of the absorber layer in air leads to improved Sb₂S₃ sensitized solar cells. A reduction in charge carrier recombination is the reason for the enhancement.