Characteristics of photovoltaic cells using monolike technology with technical and economical efficacy, and comparison with the traditional preparation method

Authors

DOI:

https://doi.org/10.15587/1729-4061.2022.265771

Keywords:

silicon, mono-like, solar cells, directional crystallization, light degradation, total efficacy, output voltage, photovoltaic, crystalline, conductivity

Abstract

The survey explores the potential for the creation of sun oriented cells from Kazakhstani p-type semiconductors, filtered by a metallurgical strategy utilizing the benefits of the mono-like innovation. As per the exploratory information, it tends to be seen that the successful lifetime shows low markers on the solar element taken from the upper piece of the ingots before the gettering system. This applies to multi-glasslike silicon cells. After phosphorus dispersion, an expansion in complete viability should be visible, which doesn't rely upon the material under study. Generally speaking, a decrease in the effective lifetime of charge carriers in silicon can happen because of the presence of a lot of metal impurities, which can create formations in the form of deposits in crystal defects or dissolve in silicon. It is shown that silicon developed by the mono-like innovation has a more drawn out transporter lifetime contrasted with standard mc-Si. Likewise, it was shown that during the time spent making a solar element, the lifetime of charge transporters builds because of the gettering impact without extra refinement processes. The benefits of the created innovation were seen at the degree of sunlight based cells, appeared in an expansion in proficiency and a reduction in the conveyance of effectiveness along the ingot level. All in all, it is shown that a solar cell made of mono-like silicon has a fairly low corruption of productivity when presented to light. Mono-like silicon sooner rather than later may turn into a forward leap in the photovoltaic business because of the great potential for the development of sunlight-based cells with high proficiency and a critical decrease in expenses

Supporting Agency

  • It was free of charge due to partnership with silicon factories and production sites for the assembly of photovoltaic cells in the city of Ust-Kamenogorsk

Author Biographies

Dastan Kalygulov, D. Serikbayev East Kazakhstan Technical University

PhD Student

Departament of Technical Physics

Sergei Plotnikov, D. Serikbayev East Kazakhstan Technical University

Professor, Doctor (PhD) of Physical and Mathematical Sciences

Department of Physics

Philippe Lay, CEO of ECM Greentech (France)

PhD in Physics

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Characteristics of photovoltaic cells using monolike technology with technical and economical efficacy, and comparison with the traditional preparation method

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Published

2022-10-30

How to Cite

Kalygulov, D., Plotnikov, S., & Lay, P. (2022). Characteristics of photovoltaic cells using monolike technology with technical and economical efficacy, and comparison with the traditional preparation method. Eastern-European Journal of Enterprise Technologies, 5(5 (119), 6–15. https://doi.org/10.15587/1729-4061.2022.265771

Issue

Vol. 5 No. 5 (119) (2022): Applied physics

Section

Applied physics

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Copyright (c) 2022 Dastan Kalygulov, Sergei Plotnikov, Philippe Lay

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