Shi Junwei, Cohen-Kleinstein Ben, Zhang Xuliang, Zhao Chenyu, Zhang Yong, Ling Xufeng, Guo Junjun, Ko Doo-Hyun, Xu Baomin, Yuan Jianyu, Ma Wanli
Department of Materials Science and Engineering, Southern University of Science and Technology, Shenzhen, 518055, People's Republic of China.
Institute of Functional Nano & Soft Materials (FUNSOM), Soochow University, 199 Ren-Ai Road, Suzhou Industrial Park, Suzhou, 215123, People's Republic of China.
Nanomicro Lett. 2023 Jun 29;15(1):163. doi: 10.1007/s40820-023-01134-1.
The introduction of hydroiodic acid (HI) manipulates the dynamic conversion of PbI into highly coordinated species to optimize the nucleation and growth kinetics. The addition of HI enables the fabrication of CsPbI perovskite quantum dots with reduced defect density, enhanced crystallinity, higher phase purity, and near-unity photoluminescence quantum yield. The efficiency of CsPbI perovskite quantum dot solar cells was enhanced from 14.07% to 15.72% together with enhanced storage stability.
All-inorganic CsPbI quantum dots (QDs) have demonstrated promising potential in photovoltaic (PV) applications. However, these colloidal perovskites are vulnerable to the deterioration of surface trap states, leading to a degradation in efficiency and stability. To address these issues, a facile yet effective strategy of introducing hydroiodic acid (HI) into the synthesis procedure is established to achieve high-quality QDs and devices. Through an in-depth experimental analysis, the introduction of HI was found to convert PbI into highly coordinated [PbI], enabling control of the nucleation numbers and growth kinetics. Combined optical and structural investigations illustrate that such a synthesis technique is beneficial for achieving enhanced crystallinity and a reduced density of crystallographic defects. Finally, the effect of HI is further reflected on the PV performance. The optimal device demonstrated a significantly improved power conversion efficiency of 15.72% along with enhanced storage stability. This technique illuminates a novel and simple methodology to regulate the formed species during synthesis, shedding light on further understanding solar cell performance, and aiding the design of future novel synthesis protocols for high-performance optoelectronic devices. [Image: see text]
The online version contains supplementary material available at 10.1007/s40820-023-01134-1.
引入氢碘酸(HI)可调控PbI向高配位物种的动态转化,以优化成核和生长动力学。添加HI能够制备出缺陷密度降低、结晶度提高、相纯度更高且光致发光量子产率接近单位值的CsPbI钙钛矿量子点。CsPbI钙钛矿量子点太阳能电池的效率从14.07%提高到了15.72%,同时存储稳定性也得到了增强。
全无机CsPbI量子点(QDs)在光伏(PV)应用中展现出了广阔的潜力。然而,这些胶体钙钛矿易受表面陷阱态恶化的影响,导致效率和稳定性下降。为解决这些问题,建立了一种简便而有效的策略,即在合成过程中引入氢碘酸(HI),以制备高质量的量子点和器件。通过深入的实验分析,发现引入HI可将PbI转化为高配位的[PbI],从而控制成核数量和生长动力学。光学和结构研究相结合表明,这种合成技术有利于提高结晶度并降低晶体缺陷密度。最后,HI的作用进一步体现在光伏性能上。最优器件的功率转换效率显著提高至15.72%,同时存储稳定性增强。该技术阐明了一种新颖且简单的方法来调控合成过程中形成的物种,有助于进一步理解太阳能电池性能,并辅助设计未来高性能光电器件的新型合成方案。[图片:见正文]
网络版包含可在10.1007/s40820-023-01134-1获取的补充材料。
