Yıl 2023,
Cilt: 1 Sayı: 2, 90 - 104, 31.12.2023
Muhammad Saleem
,
Mehmood Ali
,
Muhammad Bin-saleem
,
Muhammad Taha Bın Saleem
Kaynakça
- REFERENCES
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[CrossRef]
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Artificial photosynthesis a novel and sustainable renewable energy source: In the perspective of Saudi Arabia
Yıl 2023,
Cilt: 1 Sayı: 2, 90 - 104, 31.12.2023
Muhammad Saleem
,
Mehmood Ali
,
Muhammad Bin-saleem
,
Muhammad Taha Bın Saleem
Öz
In the present era, energy is one of the key players in the sustainable development of a coun-try from the economic, social, and environmental point of views. Saudi Arabia is one of the major oil producers in the world. Therefore, Saudi Arabia is using conventional fossil fuels as the main source of electrical energy generation. However, in order to diversify its economic sources and address environmental issues, the country has planned in Vision 2030 to exploit renewable energy resources. The objective of this study is to analyse the various sources of renewable energy in Saudi Arabia and evaluate the novel artificial photosynthesis technique in more detail. Evidence and data were reviewed from various articles, books, and conference proceedings to support this study. To conclude reviewing this technology, novel artificial pho-tosynthesis techniques were narrowed down to prove how they can be one of the fossil fuel alternatives. Various suggestions have been given to prevent setbacks and to find alternative methods to overcome limiting factors.
Kaynakça
- REFERENCES
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Accessed on Apr 26, 2016.
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2019;24:1839–1855. [CrossRef]
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[CrossRef]
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2023;21:741–764. [CrossRef]
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caused-by-humans.php. Accessed Apr 8, 2022.
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https://energyeducation.ca/encyclopedia/Renewable_and_sustainable_energy. Accessed Apr 5, 2022.
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Environ 2020;727:138534. [CrossRef]
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- [CrossRef]
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2014;15:306–312. [CrossRef]
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[CrossRef]
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- [28] Lan G, Fan Y, Shi W, You E, Veroneau SS, Lin W. Biomimetic active sites on monolayered metal–organic frameworks for artificial photosynthesis. Nature Catalysis 2022;5:1006–1018.
[CrossRef]
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1219. [CrossRef]
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[CrossRef]
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- [33] Chen HM, Chen CK, Liu RS, Wu CC, Chang WS, Chen KH, et al. A new approach to solar hydrogen production: a ZnO-ZnS solid solution nanowire array photoanode. Adv Energy Mater
2011;1:742–747. [CrossRef]
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Energy 2021;6:388–397. [CrossRef]
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CO2 reduction. J Energy Chem 2021;53:139–146. [CrossRef]
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https://www.altenergymag.com/article/2021/04/2021-top-article-artificial-photosynthesis-as-a-renewable-energy-source/34878 Accessed on Dec 19, 2023.
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- [39] Xie Y, Khoo KS, Chew KW, Devadas VV, Phang SJ, Lim HR, et al. Advancement of renewable energy technologies via artificial and microalgae photosynthesis. Bioresour Technol
2022;363:127830. [CrossRef]
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- [41] Thornton DCO. Primary production in the ocean. In: Advances in Photosynthesis–Fundamental Aspects. Intech; 2012. p. 563–588.
- [42] Walczak KA, Hutchins MJ, Dornfeld D. Energy system design to maximize net energy production considering uncertainty in scale-up: A case study in artificial photosynthesis. Procedia CIRP
2014;15:306–312. [CrossRef]
- [43] Wang Y, Seo B, Wang B, Zamel N, Jiao K, Adroher XC. Fundamentals, materials, and machine learning of polymer electrolyte membrane fuel cell technology. Energy AI 2020;1:100014.
[CrossRef]
- [44] Solargis. Photovoltaic Electricity Potential. 2022. Available at https://solargis.com
- [45] Mengele AK, Rau S. Learning from Nature’s Example: Repair Strategies in Light-Driven Catalysis. JACS Au 2022;3:36–46. [CrossRef]
- [46] Lan G, Fan Y, Shi W, You E, Veroneau SS, Lin W. Biomimetic active sites on monolayered metal–organic frameworks for artificial photosynthesis. Nature Catalysis 2022;5:1006–1018.
[CrossRef]
- [47] Qiu B, Du M, Ma Y, Zhu Q, Xing M, Zhang J. Integration of redox cocatalysts for artificial photosynthesis. Energy Environ Sci 2021;14:5260–5288. [CrossRef]
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