Silver-lean metallization and hybrid contacts via plating on screen-printed metal for silicon solar cells manufacturing

IF 8 2区 材料科学 Q1 ENERGY & FUELS
Yuan-Chih Chang, Yuchao Zhang, Li Wang, Sisi Wang, Haoran Wang, Chien-Yu Huang, Ran Chen, Catherine Chan, Brett Hallam
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Abstract

As PV manufacturing heads towards the multi-TW scale, it is required to carefully evaluate a wide range of concepts including not only efficiency and cost but also material consumption to ensure sustainable manufacturing of PV technologies. The rapid growth of PV could significantly increase the demand for several materials required in solar cells such as silver, aluminium, copper and even silicon, thereby causing dramatic price fluctuations. Furthermore, the PV manufacturing capacity would be at risk of being limited by the supply of some scarce metals, e.g. with current industrial implementations – screen printing (SP) metallization, the capacities of PERC and TOPCon could be capped at 377 GW and 227 GW with 20% of global silver supply available to the PV industry. In addition, PV systems have ~25–30 years lifespan to ensure low LCOE and emissions. Recycling alone will not provide an immediate solution to overcome the limitation of material consumption in the exponentially growing PV market. It is expected that the Ag usage needs to be reduced to no more than 5 mg/W or even 2 mg/W for all solar cell technologies to allow a multi-TW manufacturing scale without depleting the global silver supply. Therefore, further advancements in metallization technologies are critically and urgently required to significantly reduce the silver consumption of current screen-printed contacts in industrial silicon solar cells. This paper firstly presents a roadmap towards the 5 mg/W and 2 mg/W silver consumption targets with various metallization technologies and screen-printing designs. Subsequently, a hybrid plating on screen-printed metallization design was proposed to improve the performance and reduce the silver consumption of screen-printed contacts. The experimental results have demonstrated up to 1.08%abs improvements in fill factor and 0.3%abs gains in cell efficiency. In addition, up to 40%rel reductions in finger silver consumption have been achieved without any sacrifices in the electrical conductivity of such hybrid screen-printed and plated fingers. This work proposes not only a roadmap but also a promising approach to significantly reduce the Ag demand and benefit sustainable production of industrial screen-printed silicon solar cells in the TW era.

Abstract Image

Abstract Image

通过电镀丝网印刷金属实现硅太阳能电池制造中的银边金属化和混合触点
随着光伏制造向多兆瓦级迈进,需要仔细评估各种概念,不仅包括效率和成本,还包括材料消耗,以确保光伏技术的可持续制造。光伏技术的快速发展会大幅增加对太阳能电池所需的几种材料的需求,如银、铝、铜甚至硅,从而导致价格剧烈波动。此外,光伏制造能力还可能受到某些稀缺金属供应的限制,例如,在目前的工业实施--丝网印刷(SP)金属化的情况下,PERC 和 TOPCon 的产能上限分别为 377 千兆瓦和 227 千兆瓦,而光伏产业只能获得全球银供应量的 20%。此外,光伏系统的使用寿命约为 25-30 年,以确保低 LCOE 和低排放。仅靠回收利用并不能立即解决光伏市场急剧增长对材料消耗的限制。预计所有太阳能电池技术的银用量都需要降低到不超过 5 mg/W 甚至 2 mg/W,才能在不耗尽全球银供应的情况下实现多 TW 的生产规模。因此,迫切需要进一步提高金属化技术,以大幅降低目前工业硅太阳能电池中丝网印刷触点的银用量。本文首先介绍了利用各种金属化技术和丝网印刷设计实现 5 mg/W 和 2 mg/W 耗银目标的路线图。随后,提出了一种丝网印刷金属化混合电镀设计,以提高丝网印刷触点的性能并降低银消耗。实验结果表明,填充因子提高了 1.08%abs,电池效率提高了 0.3%abs。此外,在不牺牲丝网印刷和电镀混合触点导电性能的情况下,触点银消耗量最多可减少 40%abs。这项工作不仅提出了一个路线图,而且还提出了一种在 TW 时代大幅减少银需求并有利于工业丝网印刷硅太阳能电池可持续生产的可行方法。
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来源期刊
Progress in Photovoltaics
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”.
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