Team of Renewable Energies, LP2MS Laboratory, Department of Physics, Faculty of Sciences, Moulay Ismail University, B.P 11201, Meknes 50070, Morocco.
Laboratory of Chemistry-Biology Applied to the Environment, Faculty of Sciences, Moulay Ismail University, B.P 11201, Meknes 50070, Morocco.
Molecules. 2023 Mar 23;28(7):2880. doi: 10.3390/molecules28072880.
Inorganic halide perovskites of the type AMX, where A is an inorganic cation, M is a metal cation, and X is a halide anion, have attracted attention for optoelectronics applications due to their better optical and electronic properties, and stability, under a moist and elevated temperature environment. In this contribution, the electronic, optical, thermoelectric, and elastic properties of cesium lead bromide, CsPbBr, and Rb-doped CsPbBr, were evaluated using the density functional theory (DFT). The generalized gradient approximation (GGA) in the scheme of Perdew, Burke, and Ernzerhof (PBE) was employed for the exchange-correlation potential. The calculated value of the lattice parameter is in agreement with the available experimental and theoretical results. According to the electronic property results, as the doping content increases, so does the energy bandgap, which decreases after doping 0.75. These compounds undergo a direct band gap and present an energies gap values of about 1.70 eV (x = 0), 3.76 eV (x = 0.75), and 1.71 eV (x = 1). The optical properties, such as the real and imaginary parts of the dielectric function, the absorption coefficient, optical conductivity, refractive index, and extinction coefficient, were studied. The thermoelectric results show that after raising the temperature to 800 K, the thermal and electrical conductivities of the compound RbxCsPbBr increases (x = 0, 0.25, 0.50 and 1). RbCsPbBr (x = 0.75), which has a large band gap, can work well for applications in the ultraviolet region of the spectrum, such as UV detectors, are potential candidates for solar cells; whereas, CsPbBr (x = 0) and RbPbBr (x = 1), have a narrow and direct band gap and outstanding absorption power in the visible ultraviolet energy range.
类型为 AMX 的无机卤化物钙钛矿,其中 A 是无机阳离子,M 是金属阳离子,X 是卤化物阴离子,由于其在潮湿和高温环境下具有更好的光学和电子性能以及稳定性,引起了人们对光电子应用的关注。在本贡献中,使用密度泛函理论(DFT)评估了铯铅溴化物,CsPbBr 和 Rb 掺杂的 CsPbBr 的电子、光学、热电和弹性性质。交换相关势采用 Perdew、Burke 和 Ernzerhof(PBE)方案中的广义梯度近似(GGA)。晶格参数的计算值与可用的实验和理论结果一致。根据电子性质的结果,随着掺杂含量的增加,能带隙也会增加,在掺杂 0.75 后会减小。这些化合物经历直接带隙,具有约 1.70 eV(x = 0)、3.76 eV(x = 0.75)和 1.71 eV(x = 1)的能隙值。研究了光学性质,如介电函数的实部和虚部、吸收系数、光学电导率、折射率和消光系数。热电结果表明,升高温度至 800 K 后,化合物 RbxCsPbBr 的热导率和电导率增加(x = 0、0.25、0.50 和 1)。具有大带隙的 RbCsPbBr(x = 0.75)可以很好地应用于光谱的紫外区域,例如紫外探测器,是太阳能电池的潜在候选材料;而 CsPbBr(x = 0)和 RbPbBr(x = 1)具有较窄和直接的带隙,在可见光紫外能量范围内具有出色的吸收能力。
