Prospects for the Use of Film-Ceramic Photocatalysts for the Cultivation of Microalgae
( Pp. 60-69)
More about authors
Rakhimov Rustam Kh.
Doctor of Engineering; Head at the Laboratory No. 1; Institute of Materials Science of the SPA “Physics-Sun” of the Academy of Sciences of the Republic of Uzbekistan; Institute of Renewable Energy Sources
Institute of Materials Science of the SPA “Physics-Sun” of the Academy of Science of Uzbekistan
Tashkent, Republic of Uzbekistan Yermakov Vladimir P. senior research at the Laboratory No. 1; Institute of Materials Science of the Academy of Science of Uzbekistan; Tashkent, Republic of Uzbekistan Saidvaliev Temur S. chief engineer at the Institute of Materials Science
Institute of Materials Science of the SPA “Physics-Sun” of the Academy of Science of Uzbekistan
Tashkent, Republic of Uzbekistan Yermakov Vladimir P. senior research at the Laboratory No. 1; Institute of Materials Science of the Academy of Science of Uzbekistan; Tashkent, Republic of Uzbekistan Saidvaliev Temur S. chief engineer at the Institute of Materials Science
Abstract:
There are many types of microalgae that can grow in sea and fresh water, having a high lipid content in their composition. Lipids in microalgae are used for the production of biofuels, cosmetics, medicines and other products. This article is devoted to the assessment of optimal growing conditions for such microalgae, taking into account their individual spectral sensitivity in the maximum use of sunlight. This will make it possible to create film-ceramic composites that provide the greatest increase in biomass with minimal water consumption and time.
How to Cite:
Rakhimov R.Kh., Yermakov V.P., Saidvaliev T.S. Prospects for the Use of Film-Ceramic Photocatalysts for the Cultivation of Microalgae. Computational Nanotechnology. 2023. Vol. 10. No. 2. Pp. 60–69. (In Rus.) DOI: 10.33693/2313-223X-2023-10-2-60-69. EDN: BTHXIR
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Rakhimov R.Kh. Big solar furnace. Computational nanotechnology. 2019. Vol. 6. No. 2. Pp. 141–150 (In Rus.) DOI: https://doi.org/10.33693/2313-223X-2019-6-2-141-150
Rakhimov R.Kh., Rashidov Kh.K., Ermakov V.P. et al. Features of the synthesis of functional ceramics with a set of specified properties by the radiation method. Part 4. Computational nanotechnology. 2016. No. 2. Pp. 77–80. (In Rus.)
Rakhimov R.Kh., Kim E.V. US Patent No. 5,472,720. Registration date 5.12.1995.
Rakhimov R.Kh., Mukhtorov D.N. Investigation of a film-ceramic composite in a solar cell. Computational nanotechnology. 2022. Vol. 9. No. 1. Pp. 132–138. (In Rus.) DOI: https://doi.org/10.33693/2313-223X-2022-9-1-132-138
Rakhimov R.Kh., Ermakov V.P., Rakhimov M.R. Phonon transformation mechanism in ceramic materials. Computational nanotechnology. 2017. No. 4. Pp. 21–35. (In Rus.)
Rakhimov R.Kh., Ermakov V.P., Rakhimov M.R., Mukhtorov D.N. The possibilities of a polyethylene-ceramic composite in comparison with a polyethylene film in real operating conditions. Computational nanotechnology. 2022. Vol. 9. No. 2. Pp. 67–72. (In Rus.) DOI: 10.33693/2313-223X-2022-9-2-67-72
Rakhimov R.Kh., Peter J., Ermakov V.P., Rakhimov M.R. Prospects for the use of polymer-ceramic composite in the production of microalgae. Computational nanotechnology. 2019. Vol. 6. No. 4. Pp. 44–48. (In Rus.) DOI: 10.33693/2313-223X-2019-6-4-44-48
Ivanova P.V., Natalina A.A. Microalgae as a source of alternative fuel. A Young Scientist. 2020. No. 22 (312). Pp. 591–594. (In Rus.) URL: https://moluch.ru/archive/312/70907/
Gong Ya., Jiang M. Biodiesel production using microalgae. URL: https://tr-page.yandex.ru/translate?lang=en-ru&url=https%3A%2F%2Fpubmed.ncbi.nlm.nih.gov%2F21380528%2F
Microalgae is a promising agricultural crop. URL: https://infoindustria.com.ua/mikrovodorosli-perspektivnaya-selskohozyaystvennaya-kultura
Biofuels from algae. URL: https://vseonauke.com/264166560222153076/biotoplivo-iz-vodoroslej/
Microalgae is a source of alternative fuel. URL: https://cyberleninka.ru/article/n/mikrovodorosli-istochnik-alternativnogo-topliva
Chernova N.I., Kiseleva S.V., Popel’ O.S. Efficiency of the biodiesel production from microalgae. Thermal Engineering. 2014. Vol. 61. No. 6. Pp. 399–405.
Microalgae for biodiesel. URL: https://www.vo-da.ru/articles/energoeffektivnye-los/mikrovodorosli-v-biotoplive
Technology for obtaining products from microalgae. URL: https://lifelib.info/microbiology/microalgae/4.html
Plöhn M., Spain O., Sirin S. et al. Wastewater treatment. Physiol. Plant. 2021. No. 173 (2). Pp. 568–578. DOI: 10.1111/ppl.13427
Evaluation of the effectiveness of the use of microalgae for purification and post-treatment of model wastewater from heavy metal ions. URL: https://uios.fedcdo.ru/ocenka-effektivnosti-ispolzovaniya-mikrovodoroslej-dlya-ochistki-i-doochistki-modelnyh-stochnyh-vod-ot-ionov-tyazhelyh-metallov/].
Overview of processes, methods and equipment for drying and extraction of algae. URL: https://sushilka22.ru/articles/vyrashchivanie-i-pererabotka-vodoroslei
Landscaping of deserts. URL: https://www.agroxxi.ru/zhurnal-agroxxi/fakty-mnenija-kommentarii/ozelenenie-pustyn-prosto-dobav-vody.html
Gevorgiz R.G., Shmatok M.G. Lelekov A.S. Calculation of photobiosynthesis efficiency in lower phototrophs. 1. Continuous culture. Ecology of the Sea. 2005. Issue 70. Pp. 31–36. (In Rus.)
Gevorgiz R.G., Malakhov A.S. Recalculation of the illumination value of the photobioreactor into the irradiation value: Textbook. Sevastopol: LLC “Kolorit”, 2018. 60 p.
The effect of the spectral composition of light on the productivity and biochemical composition of microalgae. URL: https://uios.fedcdo.ru/vliyanie-spektralnogo-sostava-sveta-na-produktivnost-i-biohimicheskij-sostav-mikrovodoroslej/
Efimova T.V. The effect of the spectral composition of light on the structural and functional characteristics of microalgae: Abstract of dis. URL: https://www.dissercat.com/content/deistvie-spektralnogo-sostava-sveta-na-strukturnye-i-funktsionalnye-kharakteristiki-mikrovod
Nzayisenga J.C., Farge X., Groll S.L., Sellstedt A. Effects of light intensity on growth and lipid production in microalgae grown in wastewater // Biotechnology for Biofuels. 2020. Vol. 13. Art. No. 4.
Rakhimov R.Kh., Ermakov V.P., Rakhimov M.R. Application of functional ceramics in sterilization processes. Computational nanotechnology. 2021. Vol. 8. No. 1. Pp. 84–94. (In Rus.) DOI: https://doi.org/10.33693/2313-223X-2021-8-1-84-94
Rakhimov R.Kh. Big solar furnace. Computational nanotechnology. 2019. Vol. 6. No. 2. Pp. 141–150 (In Rus.) DOI: https://doi.org/10.33693/2313-223X-2019-6-2-141-150
Rakhimov R.Kh., Rashidov Kh.K., Ermakov V.P. et al. Features of the synthesis of functional ceramics with a set of specified properties by the radiation method. Part 4. Computational nanotechnology. 2016. No. 2. Pp. 77–80. (In Rus.)
Rakhimov R.Kh., Kim E.V. US Patent No. 5,472,720. Registration date 5.12.1995.
Rakhimov R.Kh., Mukhtorov D.N. Investigation of a film-ceramic composite in a solar cell. Computational nanotechnology. 2022. Vol. 9. No. 1. Pp. 132–138. (In Rus.) DOI: https://doi.org/10.33693/2313-223X-2022-9-1-132-138
Keywords:
microalgae, photocatalysts, composite films, reactors, generation, pulsed radiation, functional ceramics.
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