Understanding hydrogen and heat diffusion across c-Si/a-Si:H heterojunctions for improved thermal management in solar cells fabrication.

IF 2.9 4区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Nanotechnology Pub Date : 2025-03-05 DOI:10.1088/1361-6528/adb8f3

Riccardo Dettori, Claudio Melis, Luciano Colombo

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Abstract

c-Si/a-Si:H-based solar cells are characterized by impressive efficiencies for silicon based devices. In this paper, we present a comprehensive atomistic simulation study of the structural and transport properties of crystalline silicon and hydrogenated amorphous silicon heterostructures for photovoltaic applications. By leveraging state-of-the-art molecular dynamics simulations with a machine-learned force field, we explore the effects of thermal boundary resistance as well as hydrogen diffusion on device performance. The simulations reveal the dependence of thermal properties on crystalline orientations, cooling rates of the amorphous layer, and interface morphology. A systematic investigation of hydrogen diffusion demonstrates its impact on heat transport and structural stability, highlighting the role of moderate hydrogenation (⩽10%) and specific orientations in enhancing thermal dissipation and reducing degradation. These findings provide atomistic insights into optimizing c-Si/a-Si:H interfaces, enabling improved thermal management and long-term stability for high-performance solar cells.

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了解氢和热在c-Si/a-Si:H异质结中的扩散，以改善太阳能电池制造中的热管理。

c-Si/a-Si: h基太阳能电池具有令人印象深刻的硅基器件效率。在本文中，我们提出了一个全面的原子模拟研究的结构和输运性质的晶体硅和氢化非晶硅异质结构的光伏应用。通过利用最先进的分子动力学模拟和机器学习力场，我们探讨了热边界阻力以及氢扩散对器件性能的影响。模拟结果揭示了晶体取向、非晶层冷却速率和界面形貌对热性能的影响。系统研究了氢扩散对热传递和结构稳定性的影响，强调了适度加氢（≤10%）和特定取向在增强热耗散和减少降解中的作用。这些发现为优化c-Si/a-Si:H界面提供了原子性的见解，从而改善了高性能太阳能电池的热管理和长期稳定性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nanotechnology 工程技术-材料科学：综合

CiteScore

7.10

自引率

5.70%

发文量

820

审稿时长

2.5 months

期刊介绍： The journal aims to publish papers at the forefront of nanoscale science and technology and especially those of an interdisciplinary nature. Here, nanotechnology is taken to include the ability to individually address, control, and modify structures, materials and devices with nanometre precision, and the synthesis of such structures into systems of micro- and macroscopic dimensions such as MEMS based devices. It encompasses the understanding of the fundamental physics, chemistry, biology and technology of nanometre-scale objects and how such objects can be used in the areas of computation, sensors, nanostructured materials and nano-biotechnology.