Phys Chem Chem Phys. 2026 Apr 17. doi: 10.1039/d6cp00142d. Online ahead of print.
ABSTRACT
Organic-inorganic lead-free halide double perovskites of the general formula A2B+B3+X6 have emerged as compelling candidates to replace toxic lead-based perovskite absorbers in optoelectronic applications. Taking MA2AgBiBr6 as the host lattice, we employ first-principles calculations combined with statistical thermodynamic modeling to systematically investigate the phase stability, electronic properties, and optical absorption characteristics of four B-site alloyed systems: MA2AgSbxBi1-xBr6, MA2AgInxBi1-xBr6, MA2KxAg1-xBiBr6 and MA2TlxAg1-xBiBr6. Thermodynamic phase diagram analysis identifies critical temperatures of 395 K (Sb), 281 K (In), 391 K (K), and 417 K (Tl), respectively. Notably, MA2AgInxBi1-xBr6 is thermodynamically stable across the entire composition range at 300 K. B-site cation alloying affords precise bidirectional bandgap engineering: substitution with In3+ or K+ induces systematic bandgap widening, whereas Sb3+ or Tl+ incorporation results in progressive bandgap narrowing, thereby achieving a tunable optical bandgap spanning 2.07-2.52 eV. Importantly, this bandgap reduction is quantitatively correlated with enhanced absorption across the visible spectrum, thereby establishing a direct structure-property relationship rooted in electronic band alignment. Furthermore, In-doping drives an indirect-to-direct bandgap transition, demonstrating that B-site compositional control simultaneously governs both the magnitude and the nature (direct vs. indirect) of the fundamental bandgap. These combined attributes position the investigated lead-free double perovskites as highly promising materials for wide-bandgap top-cell absorbers in tandem solar cells and for efficient blue-green light-emitting diodes.
PMID:41995206 | DOI:10.1039/d6cp00142d
