Small-Band-Gap Halide Double Perovskites
Adam H. Slavney (Stanford University)
Linn Leppert (University of Bayreuth)
Abraham Saldivar Valdes (Stanford University)
D. Bartesaghi (Material Innovation Institute (M2i), TU Delft - ChemE/Opto-electronic Materials)
TJ Savenije (TU Delft - ChemE/Opto-electronic Materials)
Jeffrey B. Neaton (University of California, Lawrence Berkeley National Laboratory)
Hemamala I. Karunadasa (Stanford University)
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Abstract
Despite their compositional versatility, most halide double perovskites feature large band gaps. Herein, we describe a strategy for achieving small band gaps in this family of materials. The new double perovskites Cs2AgTlX6 (X=Cl (1) and Br (2)) have direct band gaps of 2.0 and 0.95 eV, respectively, which are approximately 1 eV lower than those of analogous perovskites. To our knowledge, compound 2 displays the lowest band gap for any known halide perovskite. Unlike in AIBIIX3 perovskites, the band-gap transition in AI
2BB′X6 double perovskites can show substantial metal-to-metal charge-transfer character. This band-edge orbital composition is used to achieve small band gaps through the selection of energetically aligned B- and B′-site metal frontier orbitals. Calculations reveal a shallow, symmetry-forbidden region at the band edges for 1, which results in long (μs) microwave conductivity lifetimes. We further describe a facile self-doping reaction in 2 through Br2 loss at ambient conditions.
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