Study of silicon production processes and development of solar-cell fabrication technologies

Mukashev, B.N.; Betekbaev, A. A.; Kalygulov, D. A.; Pavlov, Artem A.; Skakov, D. M.

doi:10.1134/s1063782615100164

Cited by 8 publications

(3 citation statements)

References 2 publications

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“…Solar cells are devices that convert sunlight into electricity, primarily by utilizing semiconductor materials to harness the generated electron-hole pairs through the photovoltaic process [23]. High-purity crystalline silicon, a semiconductor material, plays a pivotal role in solar cell manufacturing, serving as the foundation for both N-type and P-type silicon wafers used in solar cell fabrication [24]. The production of high-purity crystalline silicon for the photovoltaic industry involves a series of meticulous processes, including raw material selection, refining, crystal growth, and wafer slicing.…”

Section: Photovoltaic Industrymentioning

confidence: 99%

Advanced Processing Techniques and Impurity Management for High-Purity Quartz in Diverse Industrial Applications

Long,

Zhu,

Pan

et al. 2024

Minerals

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While numerous studies have explored the mineralogical characteristics and purification techniques of high-purity quartz (HPQ), discussions on impurity control during various purification processes and their applications in photovoltaics, electronics, and optics remain limited. This review delves into the adverse effects of impurities such as aluminum, iron, and sodium in the manufacturing processes of these industries, emphasizing their critical role as these impurities can degrade material performance. This paper focuses on analyzing the types of impurities found in quartz and evaluates existing purification technologies such as acid washing, ultrasonic acid washing, chlorination roasting, and calcination quenching. It highlights the limitations of current technologies in processing quartz ore and discusses the advantages of different impurity types under various technological treatments. Moreover, it explores the environmental and economic impacts of these high-purity processes, underlining the necessity for more environmentally friendly and cost-effective purification techniques. The purpose of this review is to provide a comprehensive technical and strategic framework for the use of high-purity quartz in high-tech applications, supporting future research and industrial applications in this critical material field.

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Section: Photovoltaic Industrymentioning

confidence: 99%

Advanced Processing Techniques and Impurity Management for High-Purity Quartz in Diverse Industrial Applications

Long,

Zhu,

Pan

et al. 2024

Minerals

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“…(2) 2Mg + SiO 2 = Si + 2MgO (3) Theoretically, this allows you to remove Al, Ca and Mg to very low levels, but in practice this is hampered by large heat losses occurring during this operation. In order to avoid crystallization of the melt, oxygen is purged, as a result of which an exothermic oxidation of silicon to a dioxide occurs.…”

mentioning

confidence: 99%

“…Table 1 shows the average value for the removal of Al and Ca in percent, for several issues both with and without fluxes. In the project implementation, an optimized slag purification technology using various fluxes, as well as purification by the crystallization method, was developed [3]. After conducting pilot tests, the SoG-Si obtained by the carbothermic method from the quartz of the Sarykol field after all stages of purification, as well as solar cells created from the material obtained, was investigated.…”

mentioning

confidence: 99%

High-Tech Production of Photo-Energy in Kazakhstan Based on the Sarykol Quartz Deposit

Kalygulov¹,

Klinovitskaya²,

Turmagambetov³

et al. 2019

OF THE ACADEMY OF SCIENCES OF THE REPUBLIC OF KAZAKHSTAN

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Б а с р е д а к т о р ы ф.-м.ғ.д., проф., ҚР ҰҒА академигі Ғ.М. Мұтанов Р е д а к ц и я а л қ а с ы: Жұмаділдаев А.С. проф., академик (Қазақстан) Кальменов Т.Ш. проф., академик (Қазақстан) Жантаев Ж.Ш. проф., корр.-мүшесі (Қазақстан) Өмірбаев У.У. проф. корр.-мүшесі (Қазақстан) Жүсіпов М.А. проф. (Қазақстан) Жұмабаев Д.С. проф. (Қазақстан) Асанова А.Т. проф. (Қазақстан) Бошкаев К.А. PhD докторы (Қазақстан) Сұраған Д. корр.-мүшесі (Қазақстан) Quevedo Hernando проф. (Мексика), Джунушалиев В.Д. проф. (Қырғыстан) Вишневский И.Н. проф., академик (Украина) Ковалев А.М. проф., академик (Украина) Михалевич А.А. проф., академик (Белорус) Пашаев А. проф., академик (Əзірбайжан) Такибаев Н.Ж. проф., академик (Қазақстан), бас ред. орынбасары Тигиняну И. проф., академик (Молдова) «ҚР ҰҒА Хабарлары. Физика-математикалық сериясы».

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Solar energy conversion technologies: principles and advancements

Ajarostaghi

Mousavi

2022

Solar Energy Advancements in Agriculture and Food Production Systems

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Study of silicon production processes and development of solar-cell fabrication technologies

Cited by 8 publications

References 2 publications

Advanced Processing Techniques and Impurity Management for High-Purity Quartz in Diverse Industrial Applications

Advanced Processing Techniques and Impurity Management for High-Purity Quartz in Diverse Industrial Applications

High-Tech Production of Photo-Energy in Kazakhstan Based on the Sarykol Quartz Deposit

Solar energy conversion technologies: principles and advancements

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