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Year 2019, Volume: 3 Issue: 2, 35 - 38, 15.12.2019

Habip Yusuf Hasırcı İbrahim Çelik

Abstract

References

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  • Koroneos C, Spachos T, Moussiopoulos N. Exergy Analysis of Renewable Energy Sources. Renewable Energy (2003) 28(2):295– 310. doi:10.1016/S0960-1481(01)00125-2.
  • Apergis N, Payne J. Renewable Energy Consumption and Economic Growth: Evidence From a Panel of OECD Countries. Energy Policy (2010) 38(1):656–660. doi:10.1016/j.enpol.2009.09.002.
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  • Tachibana Y, Vayssieres L, Durrant JR. Artificial Photosynthesis for Solar Water-Splitting. Nature Photonics (2012) 6(8):511–518. doi:10.1038/nphoton.2012.175.
  • Patra KK, Bharad PA, Jain V, Chinnakonda GS. Direct Solar-to- Hydrogen Generation by Quasi Artificial Leaf Approach: Possibly Scalable and Economical Device. Journal of Materials Chemistry A (2019)(7):3179–3189. doi:10.1039/c8ta11307.
  • Li J, Li H, Zhan G, Zhang L. Solar Water Splitting and Nitrogen Fixation with Layered Bismuth Oxyhalides. Accounts of Chemical Research (2017) 50(1):112–121.
  • Damerla R. Leaves That Are Not Green: A Novel Approach on Artificial leaf.
  • Noorden RV. ’Artificial Leaf’ Faces Economic Hurdle. Nature (2012). doi:10.1038/nature.2012.10703.
  • Kimura K, Yasutake D, Yamanami A, Kitano M. Spatial Examination of Leaf-boundary-layer Conductance Using Artificial Leaves for Assessment of Light Airflow Within a Plant Canopy Under Different Controlled Greenhouse Conditions. Agricultural and Forest Meteorology ([In press]) 280.
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  • Marshall J. Solar energy: Springtime for the artificial leaf. Nature (2014) 510(7503):22–24. doi:10.1038/510022a.
  • Ackerman E. Artificial Leaf Is 10 Times Better at Generating Hydrogen from Sunlight (2015). Available from: https://spectrum.ieee.org/energywise/energy/renewables/artificial- leaf-is-ten-times-better-at-generating-hydrogen-from-sunlight.
  • Wijesena R. “Let there be Hydrogen ” Said the Nano Catalyst. Ruchira Wijesena Personal Blog (2015) [cited 2019 Nov 1]. Available from: https://ninithi.wordpress.com/2015/08/05/let-there- be-hydrogen-said-the-nano-catalyst/.

Hydrogen Production by Artificial Leaf and Influence of Artificial Leaf on Renewable Energy

Year 2019, Volume: 3 Issue: 2, 35 - 38, 15.12.2019

Habip Yusuf Hasırcı İbrahim Çelik

Abstract

With the ongoing oil crises, rapid declines in non-renewable sources, emerging greenhouse gases, energy consumption, and increasing in CO2 release are increasing the importance of renewable energy. For these reasons, artificial leaf technology has been developed to both increase alternative energy production and reduce CO2 emissions. With the widespread use of new sources, it is anticipated that greenhouse gas emissions can be reduced. One of the newly discovered sources is artificial leaf technology. Hydrogen is an element found on earth in the form of oxygen compounds H2O . With this technology, water molecules are H2 produced by hydrolyzing water in a manner similar to photosynthesis in plants. With this technology, the water components, hydrogen and oxygen, are separated from each other by the help of light and converted into energy sources. Photosynthesis reaction of artificial leaf is much more effective than real leaf. The effect of the artificial solar leaf believe they can improve even more in the future. In this study, the importance of artificial leaf technology in terms of renewable energy sources and working principle are examined. In addition, the effects of this technology on energy production were investigated.

Keywords

Artificial Leaf Water Molecules Photosynthesis Alternative Energy Sources Hydrogen Production

References

  • Aresta M, Dibenedetto A, Angelini A. The Use of Solar Energy Can Enhance The Conversion of Carbon Dioxide into Energy-rich Products: Stepping Towards Artificial Photosynthesis. Philosophical Transactions of the Royal Society A (2013) 371(1996). doi:10.1098/rsta.2012.0111.
  • Panwara NL, Kaushikb SC, Kotharia S. Role of Renewable Energy Sources in Environmental Protection: A review. Renewable and Sustainable Energy Reviews (2011) 15(3):1513–1524. doi:10.1016/j.rser.2010.11.037.
  • Koroneos C, Spachos T, Moussiopoulos N. Exergy Analysis of Renewable Energy Sources. Renewable Energy (2003) 28(2):295– 310. doi:10.1016/S0960-1481(01)00125-2.
  • Apergis N, Payne J. Renewable Energy Consumption and Economic Growth: Evidence From a Panel of OECD Countries. Energy Policy (2010) 38(1):656–660. doi:10.1016/j.enpol.2009.09.002.
  • Hinrichs-Rahlwes R. Renewables 2016: Global Status Report. Report (2016).
  • Dincer I. Renewable Energy and Sustainable Development: A Crucial Review. Renewable and Sustainable Energy Reviews (2000) 4(2):157–175. doi:10.1016/S1364-0321(99)00011-8.
  • Öztürk M, Elbir A, Özek N, Yakut AK. Güneş Hidrojen Üretim Metotlarının İncelenmesi [Investigation of Solar Hydrogen Production Methods]. In: IATS’11 (2011).
  • Chen L, Tang X, Xie P, Xu J, Chen Z, Cai Z, et al. 3D Printing of Artificial Leaf with Tunable Hierarchical Porosity for CO2 Photoreduction. Chemistry of Materials (2018) 30(3). doi:10.1021/acs.chemmater.7b04313.
  • Martín AJ, Shinagawa T, Pérez-Ramírez J. Electrocatalytic Reduction of Nitrogen: From Haber-Bosch to Ammonia Artificial Leaf. Chem (2019) 5(2):263–283. doi:10.1016/ j.chempr.2018.
  • Tachibana Y, Vayssieres L, Durrant JR. Artificial Photosynthesis for Solar Water-Splitting. Nature Photonics (2012) 6(8):511–518. doi:10.1038/nphoton.2012.175.
  • Patra KK, Bharad PA, Jain V, Chinnakonda GS. Direct Solar-to- Hydrogen Generation by Quasi Artificial Leaf Approach: Possibly Scalable and Economical Device. Journal of Materials Chemistry A (2019)(7):3179–3189. doi:10.1039/c8ta11307.
  • Li J, Li H, Zhan G, Zhang L. Solar Water Splitting and Nitrogen Fixation with Layered Bismuth Oxyhalides. Accounts of Chemical Research (2017) 50(1):112–121.
  • Damerla R. Leaves That Are Not Green: A Novel Approach on Artificial leaf.
  • Noorden RV. ’Artificial Leaf’ Faces Economic Hurdle. Nature (2012). doi:10.1038/nature.2012.10703.
  • Kimura K, Yasutake D, Yamanami A, Kitano M. Spatial Examination of Leaf-boundary-layer Conductance Using Artificial Leaves for Assessment of Light Airflow Within a Plant Canopy Under Different Controlled Greenhouse Conditions. Agricultural and Forest Meteorology ([In press]) 280.
  • Nocera DG. The Artificial Leaf. Accounts of Chemical Research (2012) 45(5):767–776.
  • Noorden RV. Secrets of Artificial Leaf Revealed. Nature (2011). doi:10.1038/news.2011.564.
  • Martin RA. A Big Leap for an Artificial Leaf. MIT Technology Review (2016) [cited 2019 Oct 28]. Available from: https://www.technologyreview.com/s/601641/a-big-leap-for-an- artificial-leaf/.
  • Marshall J. Solar energy: Springtime for the artificial leaf. Nature (2014) 510(7503):22–24. doi:10.1038/510022a.
  • Ackerman E. Artificial Leaf Is 10 Times Better at Generating Hydrogen from Sunlight (2015). Available from: https://spectrum.ieee.org/energywise/energy/renewables/artificial- leaf-is-ten-times-better-at-generating-hydrogen-from-sunlight.
  • Wijesena R. “Let there be Hydrogen ” Said the Nano Catalyst. Ruchira Wijesena Personal Blog (2015) [cited 2019 Nov 1]. Available from: https://ninithi.wordpress.com/2015/08/05/let-there- be-hydrogen-said-the-nano-catalyst/.
There are 21 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Reviews
Authors

Habip Yusuf Hasırcı This is me

İbrahim Çelik

Publication Date December 15, 2019
Submission Date November 21, 2019
Published in Issue Year 2019 Volume: 3 Issue: 2

Cite

APA Hasırcı, H. Y., & Çelik, İ. (2019). Hydrogen Production by Artificial Leaf and Influence of Artificial Leaf on Renewable Energy. International Journal of Innovative Research and Reviews, 3(2), 35-38.
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