Computational Design of Mixed-valence Tin Sulfides as Solar Absorbers
Xueting Wang, Zhun Liu, Xin-Gang Zhao, Jian Lv, Koushik Biswas, and, Lijun Zhang

TL;DR
This study uses computational methods to explore the phase stability and properties of mixed-valence tin sulfides, identifying promising structures with suitable band gaps for solar energy applications.
Contribution
It provides a comprehensive computational analysis of Sn$_x$S$_y$ compounds, revealing new stable and metastable phases and their potential as solar absorbers.
Findings
Sn$_2$S$_3$ is a stable phase.
Sn$_3$S$_4$ shows marginal stability and low-energy structures.
One structure of Sn$_3$S$_4$ has a 1.43 eV band gap, suitable for solar absorption.
Abstract
Binary tin sulfides are appealing because of their simple stoichiometry and semiconducting properties and are potentially cost-effective optoelectronic materials. The multivalency of Sn allows yet more intermediate compositions, SnS, whose structures and properties are of interest.SnS is already under consideration as a mixed-valence semiconductor. Other intermediate compositions have remained elusive. Here we report a comprehensive study of phase stability of the SnS series compounds, utilizing swarm-intelligence crystal structure search method combined with first-principles energetic calculations. We find that the stability of mixed-valence SnS compounds with respect to decomposition into pure-valence SnS and SnS is in general weaker than the SnO counterparts, likely due to differences in chemical bonding. Besides identifying the…
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Taxonomy
TopicsChalcogenide Semiconductor Thin Films · Machine Learning in Materials Science · 2D Materials and Applications
