Potential-induced degradation in bifacial silicon heterojunction solar modules: Insights and mitigation strategies

IF 8 2区材料科学 Q1 ENERGY & FUELS

Progress in Photovoltaics Pub Date : 2023-12-25 DOI:10.1002/pip.3765

Olatz Arriaga Arruti, Luca Gnocchi, Quentin Jeangros, Christophe Ballif, Alessandro Virtuani

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Abstract

Potential-induced degradation (PID) may be a serious concern in photovoltaic (PV) modules and plants, particularly when approaching high system voltages (1500+ V). Here, we investigate PID occurring in bifacial rear-emitter silicon heterojunction (SHJ) solar cells encapsulated in a glass/glass (G/G) module configuration with ethylene vinyl acetate (EVA) as an encapsulant. PID testing was performed at 85°C in 85% relative humidity (RH), and the solar cells were subjected to −1 kV and +1 kV for up to 800 h. SHJ cells were found to degrade when subjected to −1 kV, and to a lesser extent when left unbiased in damp heat (DH) conditions, while the application of +1 kV prevented degradation. Although prone to PID after extended test durations, the SHJ mini-modules investigated in this study noticeably passed the industry standard (IEC 61215:2021) PID test of 96 h. The degradation was primarily characterized by losses in short-circuit current (I_SC) at the front side, followed by fill factor (FF) and open-circuit voltage (V_OC). A cross-sectional transmission electronic microscopy analysis of the laminates subjected to −1 kV highlighted a transport of sodium (Na) through the transparent conductive oxide (TCO), reaching the amorphous Si/TCO interface. The samples tested in DH conditions and with positive PID test conditions did not exhibit such a migration of Na. To account for these observations, we updated a previously proposed model describing the sensitivity of SHJ cells to water. In our degradation model, moisture in the module corrodes the glass, creating sodium hydroxide (NaOH) that then percolate through the EVA before reaching the SHJ cell. The application of a high negative bias amplifies the previous mechanism by increasing the availability of Na⁺ and also enhances the drift of Na⁺ through the EVA to the cell. Finally, we demonstrate that PID can be mitigated or suppressed at the module level by using a high-volume resistivity encapsulant with a low water vapor transmission rate (WVTR) or by encapsulating SHJ solar cells in a configuration impermeable to water (e.g., using an edge sealant).

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双面硅异质结太阳能组件中的电位诱导退化：见解和缓解策略

电位诱发降解（PID）可能是光伏（PV）模块和电站中的一个严重问题，尤其是在接近高系统电压（1500 V 以上）时。在此，我们研究了以乙烯-醋酸乙烯酯（EVA）为封装剂、封装在玻璃/玻璃（G/G）模块配置中的双面后发射极硅异质结（SHJ）太阳能电池中发生的 PID。在 85°C 和 85% 相对湿度（RH）条件下进行了 PID 测试，并对太阳能电池施加 -1 kV 和 +1 kV 电压长达 800 小时。结果发现，SHJ 电池在施加 -1 kV 电压时会发生降解，在湿热（DH）条件下不偏置时降解程度较小，而施加 +1 kV 电压则可防止降解。降解的主要特征是前端短路电流 (ISC) 损失，其次是填充因子 (FF) 和开路电压 (VOC)。对承受 -1 kV 电压的层压板进行的横截面透射电子显微镜分析表明，钠 (Na) 通过透明导电氧化物 (TCO) 传输，到达非晶态硅/TCO 界面。而在 DH 条件和正 PID 测试条件下测试的样品则没有出现这种 Na 迁移现象。为了解释这些观察结果，我们更新了以前提出的描述 SHJ 电池对水敏感性的模型。在我们的降解模型中，模块中的水分会腐蚀玻璃，产生氢氧化钠 (NaOH)，然后渗入 EVA，最后到达 SHJ 电池。高负偏压的应用通过增加 Na+ 的可用性放大了前一种机制，同时也增强了 Na+ 通过 EVA 到电池的漂移。最后，我们证明，通过使用具有低水蒸气透过率 (WVTR) 的高容量电阻率封装剂，或将 SHJ 太阳能电池封装在不透水的结构中（例如，使用边缘密封剂），可以在模块级减轻或抑制 PID。

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

Progress in Photovoltaics 工程技术-能源与燃料

CiteScore

18.10

自引率

7.50%

发文量

130

审稿时长

5.4 months

期刊介绍： Progress in Photovoltaics offers a prestigious forum for reporting advances in this rapidly developing technology, aiming to reach all interested professionals, researchers and energy policy-makers. The key criterion is that all papers submitted should report substantial “progress” in photovoltaics. Papers are encouraged that report substantial “progress” such as gains in independently certified solar cell efficiency, eligible for a new entry in the journal''s widely referenced Solar Cell Efficiency Tables. Examples of papers that will not be considered for publication are those that report development in materials without relation to data on cell performance, routine analysis, characterisation or modelling of cells or processing sequences, routine reports of system performance, improvements in electronic hardware design, or country programs, although invited papers may occasionally be solicited in these areas to capture accumulated “progress”.