Christian Schmiga scite author profile

We present a detailed study on the rear contact formation of rear-surface-passivated silicon solar cells by full-area screen printing and alloying of aluminum pastes on the locally opened passivation layer. We demonstrate that applying conventional Al pastes exhibits two main problems: 1) high contact depths leading to an enlargement of the contact area and 2) low thicknesses of the Al-doped p + Si regions in the contact points resulting in poor electron shielding. We show that this inadequate contact formation can be directly linked to the deficiently low percentage of silicon that dissolves into the Al-Si melt during alloying. Thus, by intentionally adding silicon to the Al paste, we could significantly improve the contact geometry by reducing the contact depth and enlarging the Al-p + thickness in the contact points, enabling a simple industrially feasible way for the rear contact formation of silicon solar cells.Index Terms-Aluminum alloying, local back surface field, local emitter, silicon solar cells.

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Manufacturing 100-µm-thick silicon solar cells with efficiencies greater than 20% in a pilot production line

Terheiden

Ballmann²,

Horbelt

et al. 2014

Phys. Status Solidi A

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Present address: Arizona State University, School of Electrical, Computer and Energy Engineering, 551 E. Tyler Mall, Tempe, AZ 85287, USA.Reducing wafer thickness while increasing power conversion efficiency is the most effective way to reduce cost per Watt of a silicon photovoltaic module. Within the European project 20 percent efficiency on less than 100-mm-thick, industrially feasible crystalline silicon solar cells ("20plms"), we study the whole process chain for thin wafers, from wafering to module integration and life-cycle analysis. We investigate three different solar cell fabrication routes, categorized according to the temperature of the junction formation process and the wafer doping type: p-type silicon high temperature, n-type silicon high temperature and n-type silicon low temperature. For each route, an efficiency of 19.5% or greater is achieved on wafers less than 100 mm thick, with a maximum efficiency of 21.1% on an 80-mm-thick wafer. The n-type high temperature route is then transferred to a pilot production line, and a median solar cell efficiency of 20.0% is demonstrated on 100-mm-thick wafers.

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A Study on the Charge Carrier Transport of Passivating Contacts

Feldmann

Nogay

Polzin

et al. 2018

IEEE J. Photovoltaics

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Microstructural and electrical properties of different-sized aluminum-alloyed contacts and their layer system on silicon surfaces

Krause

Woehl

Rauer

et al. 2011

Solar Energy Materials and Solar Cells

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