Tuning the Band Gap in the Halide Perovskite CsPbBr3 Through Sr Substitution Article Swipe

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Halide Band gap Perovskite (structure) Photoluminescence Semiconductor Materials science Substitution (logic) Density functional theory Optoelectronics Wide-bandgap semiconductor Direct and indirect band gaps Condensed matter physics Inorganic chemistry Crystallography Chemistry Computational chemistry Physics Computer science Programming language

Daniel B. Straus , R. J. Cava ·

YOU? · · 2022 · Open Access · · DOI: https://doi.org/10.26434/chemrxiv-2022-bctjk-v2 · OA: W4281291620

The ability to continuously tune the band gap of a semiconductor allows its optical properties to be precisely tailored for specific applications. We demonstrate that the band gap of the halide perovskite CsPbBr3 can be continuously widened through homovalent substitution of Sr2+ for Pb2+ using solid-state synthesis, creating a material with the formula CsPb1-xSrxBr3 (0 ≤ x ≤ 1). Sr2+ and Pb2+ form a solid solution in CsPb1-xSrxBr3. Pure CsPbBr3 has a band gap of 2.29(2) eV, which increases to 2.64(3) eV for CsPb0.25Sr0.75Br3. The increase in band gap is clearly visible in the color change of the materials and is also confirmed by a shift in the photoluminescence. Density-functional theory calculations support the hypothesis that Sr incorporation widens the band gap without introducing mid-gap defect states. These results demonstrate that homovalent B-site alloying can be a viable method to tune the band gap of simple halide perovskites.