Revealing the remarkable structural, electronic, elastic, and optical properties of Zn-based fluoropervskite ZnXF3 (x = Sr, Ba) employing DFT

Materials with versatile physical properties are essential for contemporary physical society, especially in electronics, renewable energy, transportation, medicine, and more. This intact capability holds the potential for a revolutionary shift towards environmentally friendly renewable energy sources. Consequently, the exploration of materials that encompass multiple functions becomes highly imperative. This study is concentrated on comprehending the physical characteristics of elastic and optoelectronic materials to propose novel, highly efficient materials suitable for photovoltaic device applications. Within this paper, the fundamental study of fluoroperovskite properties in the context of density functional theory is undertaken, employing the full potential linearized augmented plane wave approach. Specifically, fluoroperovskite ZnXF 3 (X = Sr, Ba) is scrutinized concerning its structural, electronic, optical, and elastic attributes. The optimized crystal structural parameters for both compounds are determined as 4.41 Å for ZnSrF 3 and 4.52 Å for ZnBaF 3 , employing the Birch-Murnaghan fitting approach for the unit cell energy versus unit cell volume. All fundamental physical properties are subsequently calculated using these optimized lattice constants. To address strongly correlated electron systems, the recently developed Modified Beck-Johnson potential is employed in this research. The tolerance factor “τ” is computed for both materials, yielding values of 0.98 for ZnSrF 3 and 0.86 for ZnBaF 3 , affirming the structural stability of these perovskite crystal structures. The analysis of electronic properties reveals that both compounds exhibit a metallic behavior, for ZnXF 3 (X = Sr, Ba) fluoroperovskites. Furthermore, the research explores the potential of these selected compounds by computing their optical properties within the energy range of 0–14 eV for incident photons, with a focus on potential optoelectronic applications. Additionally, mechanical properties for both materials are assessed using the IRelast package, with results indicating that ZnXF 3 (X = Sr, Ba) fluoroPerovskites are mechanically stable, resistant to abrasion, ductile, and anisotropic. The precision and accuracy of the reported findings provide strong support for the potential applications of zinc-based ZnXF 3 (X = Sr, Ba) fluoroperovskites in photovoltaic and modern semiconductor industries.