Affiliation:
1. Faculty of Material Science and Engineering, Kunming University of Science and Technology, Kunming 650093, China
2. R&D Center of Yunnan Tin Group (Holding) Co., Ltd., Kunming 650093, China
3. Sino-Platinum Metals Co., Ltd., Kunming 650093, China
Abstract
Silver powder, as the primary component of solar silver paste, significantly influences various aspects of the paste’s performance, including printing, sintering, and conductivity. This study reveals that, beyond the shape and size of the silver powders, their microstructure is a critical factor influencing the performance of both silver powders and silver pastes in solar cell applications. The growth process leads to the formation of either polycrystalline aggregated silver powder or crystal growth silver powder. Analyzing the performance characteristics of these different microstructures provides guidance for selecting silver powders for silver pastes at different sintering temperatures. Polycrystalline aggregated silver powder exhibits higher sintering activity, with a sintering initiation temperature around 450 °C. The resulting silver paste, sintered at 750 °C, demonstrates a low sheet resistance of 2.92 mΩ/sq and high adhesion of 2.13 N. This silver powder is suitable for formulating silver pastes with lower sintering temperatures. The solar cell electrode grid lines have a high aspect ratio of 0.37, showing poor uniformity. However, due to the high sintering activity of the silver powder, the glass layer dissolves and deposits more silver, resulting in excellent conductivity, a low contact resistance of the silver electrode, a low series resistance of the solar cell of 1.23 mΩ, and a high photoelectric conversion efficiency of 23.16%. Crystal growth silver powder exhibits the highest tap density of 5.52 g/cm3. The corresponding silver paste shows improved densification upon sintering, especially at 840 °C, yielding a sheet resistance of 2.56 mΩ/sq and adhesion of 3.05 N. This silver powder is suitable for formulating silver pastes with higher sintering temperatures. The solar cell electrode grid lines are uniform with the highest aspect ratio of 0.40, resulting in a smaller shading area, a high fill factor of 81.59%, and a slightly higher photoelectric conversion efficiency of 23.17% compared to the polycrystalline aggregated silver powder.
Funder
National Natural Science Foundation of China
Major Science and Technology project of Yunnan Province
Science and Technology projects of Yunnan Precious Metals Laboratory
Joint project of enterprise basic research and application basic research in Yunnan Province
Subject
General Materials Science
Reference69 articles.
1. Ohimc Contact Formation Mechanism of Silver-Aluminum Paste Metallization on the p+ Emitter of n-Type Crystalline Silicon Solar Cells;Sun;J. Electron. Mater.,2022
2. Recent advances in methods, policies and technologies at sustainable energy systems development;Guzovic;Energy,2022
3. Effect of rare metal oxide doped lead-based glass frits on the performance of crystalline silicon solar cells;Li;Sol. Energy Mater. Sol. Cells,2023
4. Effect of PbO content in glass on front silver paste ohmic contact performance of solar cell;Xie;J. Funct. Mater.,2022
5. Çiftpinar, H.E., Stodolny, M.K., Wu, Y., Janssen, G.J.M., Löffler, J., Schmitz, J., Lenes, M., Luchies, J.M., and Geerligs, L.J. (2017, January 3–5). Study of screen printed metallization for polysilicon based passivating contacts. Proceedings of the 7th International Conference on Crystalline Silicon Photovoltaics (SiliconPV), Fraunhofer ISE, Freiburg, Germany.