<p>This work investigates the physical properties of double perovskite systems <i>Cs</i><sub><i>2</i></sub><i>XSnCl</i><sub><i>6</i></sub><i> (X</i> = <i>Ca or Mg)</i> using density functional theory (DFT), focusing on their structural, mechanical, optoelectronic, and thermoelectric characteristics. These materials crystallize in cubic structures, with lattice constants of 10.71&#xa0;Å and 10.42&#xa0;Å for <i>Cs</i><sub><i>2</i></sub><i>CaSnCl</i><sub><i>6</i></sub> and <i>Cs</i><sub><i>2</i></sub><i>MgSnCl</i><sub><i>6</i></sub>, respectively. Mechanical stability assessments confirm that both materials are stable in the cubic phase. Furthermore, mechanical stress analysis clearly demonstrates that both compounds are mechanically stable and exhibit anisotropy. However, <i>Cs</i><sub><i>2</i></sub><i>CaSnCl</i><sub><i>6</i></sub> exhibits ductile behavior, whereas <i>Cs</i><sub><i>2</i></sub><i>MgSnCl</i><sub><i>6</i></sub> is brittle. The computed band gaps are 4.23&#xa0;eV for <i>Cs</i><sub><i>2</i></sub><i>CaSnCl</i><sub><i>6</i></sub> and 3.40&#xa0;eV for <i>Cs</i><sub><i>2</i></sub><i>MgSnCl</i><sub><i>6</i></sub>, indicating their potential as wide-bandgap materials. Optical analysis reveals strong ultraviolet absorption, positioning these materials as promising candidates for UV-sensitive optoelectronic applications. Additionally, thermoelectric evaluations at room temperature show high Seebeck coefficients, enhanced electrical conductivity, and reduced electronic thermal conductivity. The dimensionless figures of merit (ZT) are 0.77 and 0.72 for <i>Cs</i><sub><i>2</i></sub><i>CaSnCl</i><sub><i>6</i></sub> and <i>Cs</i><sub><i>2</i></sub><i>MgSnCl</i><sub><i>6</i></sub>, respectively, highlighting their suitability for thermoelectric device applications.</p>

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A DFT study of physical properties of double perovskites Cs2XSnCl6 (X = Ca or Mg)

  • S. El Kamli,
  • Y. Selmani,
  • A. Jabar,
  • L. Bahmad,
  • A. Kassou-Ou-Ali

摘要

This work investigates the physical properties of double perovskite systems Cs2XSnCl6 (X = Ca or Mg) using density functional theory (DFT), focusing on their structural, mechanical, optoelectronic, and thermoelectric characteristics. These materials crystallize in cubic structures, with lattice constants of 10.71 Å and 10.42 Å for Cs2CaSnCl6 and Cs2MgSnCl6, respectively. Mechanical stability assessments confirm that both materials are stable in the cubic phase. Furthermore, mechanical stress analysis clearly demonstrates that both compounds are mechanically stable and exhibit anisotropy. However, Cs2CaSnCl6 exhibits ductile behavior, whereas Cs2MgSnCl6 is brittle. The computed band gaps are 4.23 eV for Cs2CaSnCl6 and 3.40 eV for Cs2MgSnCl6, indicating their potential as wide-bandgap materials. Optical analysis reveals strong ultraviolet absorption, positioning these materials as promising candidates for UV-sensitive optoelectronic applications. Additionally, thermoelectric evaluations at room temperature show high Seebeck coefficients, enhanced electrical conductivity, and reduced electronic thermal conductivity. The dimensionless figures of merit (ZT) are 0.77 and 0.72 for Cs2CaSnCl6 and Cs2MgSnCl6, respectively, highlighting their suitability for thermoelectric device applications.