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使用硫属钙钛矿BaSnS提高钙钛矿太阳能电池性能:一项器件模拟研究。

Enhancing perovskite solar cell performance using a BaSnS chalcogenide perovskite: a device simulation study.

作者信息

Khan Mohammad Yasin Hayat, Hasan Sayed Sahriar, Rahman Md Zillur, Rasheduzzaman Md, Hasan Md Zahid

机构信息

Materials Research and Simulation Lab, Department of Electrical and Electronic Engineering, International Islamic University Chittagong Kumira Chittagong 4318 Bangladesh

Department of Electrical and Electronic Engineering, International Islamic University Chittagong Kumira Chittagong 4318 Bangladesh.

出版信息

RSC Adv. 2025 Sep 22;15(41):34643-34668. doi: 10.1039/d5ra04940g. eCollection 2025 Sep 17.

DOI:10.1039/d5ra04940g
PMID:40989512
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12451527/
Abstract

This study explores the potential of BaSnS, a tin-based chalcogenide perovskite, as a lead-free absorber material using density functional theory (DFT), where the hybrid functional HSE06 is utilized to investigate its structural, electronic, and optical properties. This compound exhibits dynamic stability with no imaginary phonon frequencies and possesses an indirect bandgap of 1.535 eV, making it well-suited for photovoltaic applications. Its favorable optical characteristics including a high absorption coefficient exceeding 10 cm in the visible range and a static dielectric constant of 8.55 (unitless, relative to vacuum permittivity) further affirm its suitability as a solar absorber. In addition, comprehensive device simulations using SCAPS-1D are performed to evaluate the photovoltaic performance of BaSnS-based perovskite solar cells (PSCs) with various electron transport layers (ETLs) including ZnS, SnS, C, and LBSO. The ITO/ZnS/BaSnS/Pt structure demonstrates the highest efficiency, achieving a power conversion efficiency (PCE) of 25.93%, an open-circuit voltage ( ) of 1.136 V, and a short-circuit current density ( ) of 26.65 mA cm. The influence of the absorber and ETL thickness, defect density, series and shunt resistances, and operating temperature on the cell performance is systematically analyzed. The findings reveal that the optimized absorber thickness (1.0 µm) and minimized defect density significantly enhance the efficiency. Furthermore, its temperature sensitivity and recombination dynamics are examined through quantum efficiency (QE), - analysis, and Mott-Schottky profiling. This combined theoretical and numerical investigation not only highlights BaSnS as a promising candidate for future lead-free PSCs but also provides a foundation for further experimental validation and device engineering.

摘要

本研究利用密度泛函理论(DFT)探索了锡基硫族钙钛矿BaSnS作为无铅吸收材料的潜力,其中采用杂化泛函HSE06来研究其结构、电子和光学性质。该化合物具有动态稳定性,无虚声子频率,间接带隙为1.535 eV,非常适合用于光伏应用。其良好的光学特性,包括在可见光范围内超过10 cm的高吸收系数和8.55的静态介电常数(相对于真空介电常数,无量纲),进一步证实了其作为太阳能吸收体的适用性。此外,使用SCAPS-1D进行了全面的器件模拟,以评估基于BaSnS的钙钛矿太阳能电池(PSC)与包括ZnS、SnS、C和LBSO在内的各种电子传输层(ETL)的光伏性能。ITO/ZnS/BaSnS/Pt结构表现出最高效率,功率转换效率(PCE)达到25.93%,开路电压( )为1.136 V,短路电流密度( )为26.65 mA cm 。系统地分析了吸收体和ETL厚度、缺陷密度、串联和并联电阻以及工作温度对电池性能的影响。研究结果表明,优化的吸收体厚度(1.0 µm)和最小化的缺陷密度显著提高了效率。此外,通过量子效率(QE)、 - 分析和莫特 - 肖特基剖面分析了其温度敏感性和复合动力学。这种理论与数值相结合的研究不仅突出了BaSnS作为未来无铅PSC的有前途的候选材料,而且为进一步的实验验证和器件工程提供了基础。

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