%0 Journal Article
%T 能带工程改善硫化锑太阳能电池的方法<br>Methods of Energy Band Engineering for Improving Antimony Sulfide Solar Cells
%A 陈耀威
%A 姚敏
%A 安嘉凯
%A 戎沿锴
%J Modern Physics
%P 29-35
%@ 2161-0924
%D 2025
%I Hans Publishing
%R 10.12677/mp.2025.153004
%X 硫化锑(Sb<sub>2</sub>S<sub>3</sub>)作为一种低成本、环境友好且带隙可调(1.7~1.8 eV)的光伏材料&#65292;在薄膜太阳能电池领域展现出巨大潜力&#65292;但其效率受限于载流子迁移率低、界面复合损失及能级失配等问题。本文提出一种基于后硒化处理的能带工程策略&#65292;通过硒(Se)原位取代硫(S)形成梯度合金化层&#65292;优化Sb<sub>2</sub>S<sub>3</sub>的能带结构及界面特性。以半水酒石酸锑钾和五水合硫代硫酸钠为前驱体&#65292;采用水热沉积法制备Sb<sub>2</sub>S<sub>3</sub>薄膜&#65292;并通过硒化退火工艺(350&#8451;)实现能带调控。实验表明&#65292;后硒化处理使Sb<sub>2</sub>S<sub>3</sub>带隙从1.7 eV降至1.65 eV&#65292;导带偏移减少0.05 eV&#65292;显著改善了与电子传输层(ETL)的能级匹配&#65292;抑制了界面复合。优化后的器件开路电压(V<sub>OC</sub>)从0.57 V提升至0.64 V&#65292;填充因子(FF)从41.06%增至44.81%&#65292;短路电流密度(J<sub>SC</sub>)从10.97 mA&#183;cm<sup>&#8722;</sup><sup>2</sup>提高至12.49 mA&#183;cm<sup>&#8722;</sup><sup>2</sup>&#65292;光电转换效率(PCE)达3.60%&#65292;较未处理对照组提升近40%。EQE光谱显示400~700 nm波长范围内光响应显著增强。本研究创新性地通过无掺杂后硒化工艺实现了能带工程调控&#65292;为低成本、高效Sb<sub>2</sub>S<sub>3</sub>太阳能电池的开发提供了新思路&#65292;同时为硫系化合物在叠层电池及柔性光伏中的应用奠定基础。<br>Antimony sulfide (Sb<sub>2</sub>S<sub>3</sub>), as a low-cost, environmentally friendly photovoltaic material with tunable bandgap (1.7~1.8 eV), exhibits significant potential in thin-film solar cells. However, its efficiency is limited by low carrier mobility, interfacial recombination losses, and energy-level mismatch. This study proposes a band engineering strategy based on post-selenization treatment, where selenium (Se) <i>in situ</i> substitutes sulfur (S) to form a gradient alloying layer, thereby optimizing the band structure and interfacial properties of Sb<sub>2</sub>S<sub>3</sub>. Sb<sub>2</sub>S<sub>3</sub> thin films were prepared via hydrothermal deposition using potassium antimony tartrate hemihydrate and sodium thiosulfate pentahydrate as precursors, followed by selenization annealing (350&#730;C) for band structure modulation. Experimental results showed that post-selenization reduced the bandgap of Sb<sub>2</sub>S<sub>3</sub> from 1.7 eV to 1.65 eV and decreased the conduction band offset by 0.05 eV, significantly improving energy-level alignment with the electron transport layer (ETL) and suppressing interfacial recombination. The optimized devices achieved an open-circuit voltage (V<sub>OC</sub>) of 0.64 V (vs. 0.57 V for the control), a fill factor (FF) of 44.81% (vs. 41.06%), a short-circuit current density (J<sub>SC</sub>) of 12.49 mA&#183;cm<sup>&#8722;</sup><sup>2</sup> (vs. 10.97 mA&#183;cm<sup>&#8722;</sup><sup>2</sup>), and a photoelectric conversion efficiency (PCE) of 3.60%, representing a nearly 40% improvement over the untreated group. EQE spectra demonstrated enhanced photoresponse in the 400~700 nm wavelength range. This work innovatively realizes band engineering through a
%K 硫化锑太阳能电池&#65292
%K 能带工程&#65292
%K 光电转换效率<br>Antimony Sulfide Solar Cells
%K Energy Band Engineering
%K Photoelectric Conversion Efficiency
%U http://www.hanspub.org/journal/PaperInformation.aspx?PaperID=115231