<p>In this work, we use density functional theory (DFT) to thoroughly analyze the structural, electrical, optical, and thermoelectric characteristics of halide double perovskites Rb<sub>2</sub>AsAuX<sub>4</sub> (X = Br, Cl). Both compounds’ structural stability is confirmed by the optimized lattice characteristics, with Rb<sub>2</sub>AsAuBr<sub>4</sub> showing somewhat larger cell dimensions than Rb<sub>2</sub>AsAuCl<sub>4</sub>. Indirect band gaps of 0.338 eV (Br) and 0.885 eV (Cl), which are within the optimal range for solar applications, are shown by electronic band structure simulations. Strong absorption coefficients in the visible region above 1.2 × 10<sup>1</sup> cm<sup>−1</sup> are shown in optical spectra, suggesting great potential for solar energy harvesting. High Seebeck coefficients of up to 310&#xa0;μV/K (Br) and 285&#xa0;μV/K (Cl) at ambient temperature are shown by thermoelectric analysis, together with electrical conductivities that facilitate effective charge transfer. Thermoelectric performance is further improved by the comparatively low thermal conductivity (0.9–1.1 W/m·K). Together, our findings demonstrate Rb<sub>2</sub>AsAuX<sub>4</sub>’s versatility and establish Rb<sub>2</sub>AsAuBr<sub>6</sub> and Rb<sub>2</sub>AsAuCl<sub>4</sub> as viable options for next optoelectronic and energy-harvesting applications.</p>

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Synergistic optoelectronic and thermoelectric performance in Rb2AsAuBr6 and Rb2AsAuCl6 double perovskites for multifunctional energy conversion

  • K. Bouferrache,
  • M. A. Ghebouli,
  • M. Fatmi,
  • Ghadah Sheetah,
  • S. Alomairy,
  • Mustafa Jaipallah Abdelmageed Abualreish,
  • Aseel Smerat,
  • Murat Yaylacı

摘要

In this work, we use density functional theory (DFT) to thoroughly analyze the structural, electrical, optical, and thermoelectric characteristics of halide double perovskites Rb2AsAuX4 (X = Br, Cl). Both compounds’ structural stability is confirmed by the optimized lattice characteristics, with Rb2AsAuBr4 showing somewhat larger cell dimensions than Rb2AsAuCl4. Indirect band gaps of 0.338 eV (Br) and 0.885 eV (Cl), which are within the optimal range for solar applications, are shown by electronic band structure simulations. Strong absorption coefficients in the visible region above 1.2 × 101 cm−1 are shown in optical spectra, suggesting great potential for solar energy harvesting. High Seebeck coefficients of up to 310 μV/K (Br) and 285 μV/K (Cl) at ambient temperature are shown by thermoelectric analysis, together with electrical conductivities that facilitate effective charge transfer. Thermoelectric performance is further improved by the comparatively low thermal conductivity (0.9–1.1 W/m·K). Together, our findings demonstrate Rb2AsAuX4’s versatility and establish Rb2AsAuBr6 and Rb2AsAuCl4 as viable options for next optoelectronic and energy-harvesting applications.