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引用次数: 0
摘要
有人提出,热辅助强光浸泡是进一步提高硅异质结(SHJ)太阳能电池性能的有效后处理方法。本研究旨在区分热量和光照对 SHJ 接触堆不同层(掺杂层和未掺杂层)的影响。研究发现,当升温和照明同时有效发挥作用时,可显著减少界面重组。钝化的协同效应显示出约 0.5 eV 的热活化能。这可能是由于晶体硅晶片中光生成的电子/空穴对几乎吸收了所有的入射光。通过区分光效应和热效应对 p 型和 n 型掺杂氢化非晶硅(a-Si:H)层电导率的影响,可以证明只有热效应才会导致观察到的电导率上升。根据数值设备模拟,开路电压增强的主要原因是晶体硅/本征 a-Si:H 界面的缺陷态密度降低。此外,填充因子的变化高度依赖于界面缺陷密度和 p 型 a-Si:H 带尾状态密度的变化。
Insights into the Heat-Assisted Intensive Light-Soaking Effect on Silicon Heterojunction Solar Cells
Heat-assisted intensive light soaking has been proposed as an effective posttreatment to further enhance the performance of silicon heterojunction (SHJ) solar cells. In the current study, it is aimed to distinguish the effects of heat and illumination on different (doped and undoped) layers of the SHJ contact stack. It is discovered that both elevated temperature and illumination are necessary to significantly reduce interface recombination when working effectively together. The synergistic effect on passivation displays a thermal activation energy of approximately 0.5 eV. This is likely due to the photogenerated electron/hole pairs in the c–Si wafer, where nearly all of the incident light is absorbed. By distinguishing between the effects of light and heat effects on the conductivity of p- and n-type doped hydrogenated amorphous silicon (a–Si:H) layers, it is demonstrated that only heat is accountable for the observed rise in conductivity. According to numerical device simulations, the significant contribution to the open-circuit voltage enhancement arises from the reduced density of defect states at the c–Si/intrinsic a–Si:H interface. In addition, the evolution of the fill factor is highly dependent on changes in interface defect density and the band tail state density of p-type a–Si:H.
Solar RRLPhysics and Astronomy-Atomic and Molecular Physics, and Optics
CiteScore
12.10
自引率
6.30%
发文量
460
期刊介绍:
Solar RRL, formerly known as Rapid Research Letters, has evolved to embrace a broader and more encompassing format. We publish Research Articles and Reviews covering all facets of solar energy conversion. This includes, but is not limited to, photovoltaics and solar cells (both established and emerging systems), as well as the development, characterization, and optimization of materials and devices. Additionally, we cover topics such as photovoltaic modules and systems, their installation and deployment, photocatalysis, solar fuels, photothermal and photoelectrochemical solar energy conversion, energy distribution, grid issues, and other relevant aspects. Join us in exploring the latest advancements in solar energy conversion research.
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