学术文献库

Reliable chemical state analysis of Sn semiconductors by XPS is hindered by the marginal observed shift in the Sn 3d region. For hybrid Sn-based perovskites especially, errors associated with charge referencing can easily exceed chemistry-related shifts. Studies based on the modified Auger parameter $α'$ provide a suitable alternative and have been used previously to resolve different chemical states in Sn alloys and oxides. However, the meaningful interpretation of Auger parameter variations on Sn-based perovskite semiconductors requires fundamental studies. In this work, we perform a comprehensive Auger parameter study through systematic compositional variations of Sn halide perovskites. We find that in addition to the oxidation state, $α'$ is highly sensitivity to the composition of the halide-site, inducing shifts of up to $Δα' = 2 eV$ between ASnI$_3$ and ASnBr$_3$ type perovskites. The reported dependencies of $α'$ on the Sn oxidation state, coordination and local chemistry provide a framework that enables reliable tracking of degradation as well as X-site interaction for Sn-based perovskites and related compounds. The higher robustness and sensitivity of such studies not only enables more in-depth surface analysis of Sn-based perovskites than previously performed, but also increases reproducibility across laboratories.