Himanshu Bhatt, Ramchandra Saha, Tanmay Goswami, Sangeetha C. K., Kaliyamoorthy Justice Babu, Gurpreet Kaur, Ayushi Shukla, Mahammed Suleman Patel, Sachin R. Rondiya, Nelson Y. Dzade, Hirendra N. Ghosh
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引用次数: 0
摘要
光伏设备的性能取决于吸收层的光吸收能力和激发态电荷载流子的寿命。由于二维过渡金属二掺杂物(TMDCs)具有很强的光-物质相互作用、出色的电荷载流子迁移率、较长的电子-空穴扩散长度和更高的稳定性,因此将其与包晶结合在异质结中显示出巨大的潜力。然而,TMDC 中快速的电荷载流子重组和界面上较差的电荷分离限制了它们的效率。因此,带状结构调制是改善这些异质结电荷分离的关键方法。在此,我们制作了 CsPbI3 和 WS2 异质结(CPI-WS2),并通过在 CPI 中加入镍原子调制了带能级。实验和理论分析表明,掺杂镍原子可同时提升 CPI 的价带和导带,将 CPI-WS2 的准 II 型能带排列转变为 II 型构型。掺杂异质系统在界面上显示出大量的电荷载流子分离,而 TMDC 则充当了电子提取器的角色。这种较高的电荷分离显著提高了调制异质结内的光电流和光致发光性。这项研究强调了掺杂引发的带级工程对于促进 TMDC-perovskite 界面的电荷载流子分离的重要性,从而推动了基于异质结的先进光学器件的设计。
Charge Transfer Modulation in the α-CsPbI3/WS2 Heterojunction via Band-Tailoring with Elemental Ni Doping
The performance of photovoltaic devices relies on the light-absorbing capability of the absorber layer and the lifetime of excited-state charge carriers. Combining two-dimensional transition metal dichalcogenides (TMDCs) with perovskites in heterojunctions shows immense potential due to their strong light–matter interaction, excellent charge carrier mobility, long electron–hole diffusion length, and improved stability. However, fast charge carrier recombination in TMDCs and poor charge separation at the interface limit their efficiency. In this direction, band structure modulation can be a key approach to improving the charge separation in these heterojunctions. Herein, we have fabricated a heterojunction of CsPbI3 and WS2 (CPI-WS2) and modulated the band levels by incorporating Ni atoms into CPI. Experimental and theoretical analyses reveal that Ni-doping elevates both the valence and conduction bands of CPI, transforming the quasi-type II band arrangement of CPI-WS2 into a type II configuration. The doped heterosystem shows substantial charge carrier separation at the interface, with TMDC acting as the electron extractor. This higher segregation of charges notably improves the photocurrent and photoresponsivity within the modulated heterojunctions. This study underscores the importance of doping-induced band-level engineering for promoting charge carrier separation at the TMDC-perovskite interface, advancing the design of advanced optical devices based on heterojunctions.
期刊介绍:
Published as soon as accepted and summarized in monthly issues, ACS Photonics will publish Research Articles, Letters, Perspectives, and Reviews, to encompass the full scope of published research in this field.
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