‘Just-Clean-Enough’: Optimization of Wet Chemical Cleaning Processes for Crystalline Silicon Solar Cells

Michael Haslinger; M. Soha; S. Robert; M. Claes; Paul W. Mertens; J. John

doi:10.4028/www.scientific.net/SSP.255.344

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Quantitative Analysis of Trace Metallic Contamination on III-V Compound Semiconductor Surfaces
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Oxidation of Si Surfaces: Effect of Ambient Air and Water Treatments on Surface Charge and Interface State Density
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Surface Optimization of Random Pyramid Textured Silicon Substrates for Improving Heterojunction Solar Cells
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‘Just-Clean-Enough’: Optimization of Wet Chemical Cleaning Processes for Crystalline Silicon Solar Cells
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Optimization of EUV Reticle Cleaning by Evaluation of Chemistries on Wafer-Based Mimic Test Structures
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HomeSolid State PhenomenaSolid State Phenomena Vol. 255‘Just-Clean-Enough’: Optimization of Wet Chemical...

‘Just-Clean-Enough’: Optimization of Wet Chemical Cleaning Processes for Crystalline Silicon Solar Cells

Abstract:

Advanced concepts for photovoltaic silicon solar cells, especially high-efficiency n-type solar cells, requires appropriate wet cleaning treatment in order to remove metallic contamination prior to high temperature processes like diffusion and passivation [1]. The cost of the cleaning process should be as low as possible that requires an optimized usage of the chemicals by increasing process tank lifetimes and developing dedicated feed and bleed recipes. The just clean enough concept has been developed to fulfil the needs of PV industry to minimize the consumption of chemicals. When the dominant contamination metal is identified in quality and quantity, a dedicated wet chemical cleaning process can be applied to remove the metal concentration from the semiconductor surface under a specified limit with the minimum volume on cleaning solution. The paper describes how to optimize a dedicated wet cleaning process for prominent metal impurities like Fe, Cu, Cr, Ti, Co and Zn. For each metal an exchange volume is determined to develop a feed and bleed recipe. The accumulation of the metal impurities in the process tank is calculated and process tank lifetimes are predicted.

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Solid State Phenomena (Volume 255)

Pages:

344-347

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.255.344

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Online since:

September 2016

Authors:

Michael Haslinger*, M. Soha, S. Robert, M. Claes, Paul W. Mertens, J. John

Keywords:

Langmuir Adsorption Isotherm, Metal Contamination, Silicon Solar Cells, Silicon Surface Clean

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