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Analysis of Biological, Chemical, and Physical Parameters to Evaluate the Effect of Floating Solar PV in Mahoni Lake, Depok, Indonesia: Mesocosm Experiment Study

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Waters provide essential needs both for human societies as well as natural ecosystems. Floating solar PV (FPV) applications on water bodies are currently in strong demand worldwide. Floating solar PV system is a new concept in renewable energy with the solar plants by harnessing available water surface, such in dams, lakes, and other water bodies. Although the floating solar PV industry is becoming more and more popular, the study on the biological, chemical, and physical properties effects of using FPV cover on natural water coverage – especially in tropical countries – has not been widely carried out yet. This paper aimed to evaluate the effect of floating solar PV on temperature, DO (dissolved oxygen), TDS (total dissolved solids), total phosphorus concentration, and chlorophyll-a concentration using mesocosm experiments to understand the biological, chemical, and physical process under closed environment. The experiment was conducted in a natural water body, Mahoni Lake, in which a total amount of 7 water samples were collected from each mesocosms. The results show that the floating solar PV reduces the average temperature, DO, conductivity, TDS, and chlorophyll-a concentration changes (p-value < 0.05); and the floating solar PV does not directly reduce the average total phosphorus concentration due to high probability of thermal stratification (p-value > 0.05).
Słowa kluczowe
Rocznik
Strony
201--207
Opis fizyczny
Bibliogr. 27 poz., rys.
Twórcy
  • Department of Civil Engineering, Faculty of Engineering, Universitas Indonesia, Kampus UI Depok, Depok 16424, Indonesia
  • Department of Civil Engineering, Faculty of Engineering, Universitas Indonesia, Kampus UI Depok, Depok 16424, Indonesia
  • Department of Electrical Engineering, Faculty of Engineering, Universitas Indonesia, Kampus UI Depok, Depok 16424, Indonesia
  • Tropical Renewable Energy Center, Faculty of Engineering, Universitas Indonesia, Kampus UI Depok 16424, Indonesia
  • Tropical Renewable Energy Center, Faculty of Engineering, Universitas Indonesia, Kampus UI Depok 16424, Indonesia
Bibliografia
  • 1. Chang Y., Ku C., Yeh N. 2014. Solar powered artificial floating island for landscape ecology and water quality improvement. Ecological Engineering, 69(369), 8–16.
  • 2. Château P., Wunderlich R.F., Wang T., Lai H., Chen C., Chang F. 2019. Mathematical modeling suggests high potential for the deployment of floating photovoltaic on fish ponds. Science of the Total Environment, 687, 654–666.
  • 3. Choi Y. 2014. A Study on Power Generation Analysis of Floating PV System Considering Environmental Impact. International Journal of Software Engineering and Its Applications, 8(1), 75–84.
  • 4. Gillette J.P., Schulz K.L., Teece M.A. 2014. Light Apparatus for Mesocosm Photo-manipulation (LAMP): An inexpensive waterproof lighting device for within-lake mesocosm experiments. Limnology and Oceanography: Methods, 12(AUG), 592–603.
  • 5. Gorde S.P., Jadhav M.V. 2013. Assessment of Water Quality Parameters : A Review. International Journal of Engineering Research and Applications, 3(6), 2029–2035.
  • 6. Haas J., Khalighi J., Fuente A., De Gerbersdorf S.U., Nowak W., Chen P. 2020. Floating photovoltaic plants: Ecological impacts versus hydropower operation flexibility. Energy Conversion and Management, 206.
  • 7. Havens K.E., Jin K.R., Iricanin N., James R.T. 2007. Phosphorus dynamics at multiple time scales in the pelagic zone of a large shallow lake in Florida, USA. Hydrobiologia, 581(1), 25–42.
  • 8. Landkildehus F., Søndergaard M., Beklioglu M., Adrian R., Angeler D.G., Hejzlar J., Jeppesen E. 2014. Climate change effects on shallow lakes: Design and preliminary results of a cross-European climate gradient mesocosm experiment. Estonian Journal of Ecology, 63(2), 71–89.
  • 9. Lereng I.H. 2018. Study on the Cooling Effect for Floating PV Modules in Thermal Contact with Water and the Potential for Modelling Floating PV. Norwegian University of Life Sciences.
  • 10. Li W., Guo Y., Fu K. 2011. Enclosure experiment for influence on algae growth by shading light. Procedia Environmental Sciences, 10(B), 1823–1828.
  • 11. Machado L.F., de Assis Leite D.C., da Costa Rachid C.T.C., Paes J.E., Martins E.F., Peixoto R.S., Rosado A.S. 2019. Tracking Mangrove Oil Bioremediation Approaches and Bacterial Diversity at Different Depths in an in situ Mesocosms System. Frontiers in Microbiology, 10(September), 1–14.
  • 12. Patil S.S., Wagh M.M., Shinde N.N. 2017. A review on floating solar photovoltaic power plants. International Journal of Scientific & Engineering Research, 8(6), 789–794.
  • 13. Petersen J.E., Kemp W.M. 2019. Mesocosms: Enclosed experimental ecosystems in ocean science. Encyclopedia of Ocean Sciences (3 ed.). Elsevier Inc.
  • 14. Rocha R.R.A., Thomaz S.M., Carvalho P., Gomes L.C. 2009. Modeling chlorophyll-a and dissolved oxygen concentration in tropical floodplain lakes (Paraná River, Brazil). Brazilian Journal of Biology, 69(2), 491–500.
  • 15. Sahu A., Yadav N., Sudhakar K. 2016. Floating photovoltaic power plant: A review. Renewable and Sustainable Energy Reviews, 66, 815–824.
  • 16. Santafé M.R., Soler J.B.T., Romero F.J.S., Gisbert P.S.F., Gozálvez J.J.F., Gisbert C.M.F. 2014. Theoretical and experimental analysis of a floating photovoltaic cover for water irrigation reservoirs. Energy, 67, 246–255.
  • 17. Šorf M., Brandl Z., Znachor P., Vašek M. 2013. Floating large-volume mesocosms as a simple, lowcost experimental design suitable for the variety of lakes and reservoirs. Fundamental and Applied Limnology, 183, 41–48.
  • 18. Stewart R.I.A., Dossena M., Bohan D.A., Jeppesen E., Kordas R.L., Ledger M.E., Woodward G. 2013. Mesocosm Experiments as a Tool for Ecological Climate-Change Research. Advances in Ecological Research Elsevier Ltd, 1(48).
  • 19. Syahindra K. D., Ma’Arif S., Widayat A.A., Fauzi A.F., Setiawan E.A. 2021. Solar PV system performance ratio evaluation for electric vehicles charging stations in transit oriented development (TOD) areas. E3S Web of Conferences, 231.
  • 20. Taboada M.E., Cáceres L., Graber T., Galleguillos H., Cabeza L.F., Rojas R. 2016. Solar water heating system and photovoltaic floating cover to reduce evaporation: Experimental results and modeling. Renewable Energy.
  • 21. Tonetta D., Anton P., Obrador B., Pena L., Brandão M., Silva L., Barbosa R. 2018. Effects of nutrients and organic matter inputs in the gases CO2 and O2: A mesocosm study in a tropical lake. Limnologica, 69(Feb.), 1–9.
  • 22. Weber-Scannell P.K., Duffy L.K. 2007. Effects of total dissolved solids on aquatic organisms: A review of literature and recommendation for salmonid species. American Journal of Environmental Sciences, 3(1), 1–6.
  • 23. Wetzel R.G. 2001. Shallow Lakes and Ponds. Limnology, 625–630.
  • 24. Widayat A.A., Ma’arif S., Syahindra K.D., Fauzi A.F., Adhi Setiawan E. 2020. Comparison and Optimization of Floating Bifacial and Monofacial Solar PV System in a Tropical Region. 2020 9th International Conference on Power Science and Engineering, ICPSE 2020, 66–70.
  • 25. Winder M., Berger S.A., Lewandowska A., Aberle N., Lengfellner K., Sommer U., Diehl S. 2012. Spring phenological responses of marine and freshwater plankton to changing temperature and light conditions. Marine Biology, 159(11), 2491–2501.
  • 26. Yeh T., Wu M., Cheng C., Hsu Y. 2014. A Study and Analysis on the Physical Shading Effect of Water Quality Control in Constructed Wetlands. Journal of Civil & Environmental Engineering, 4(3).
  • 27. Zingel P., Cremona F., Nõges T., Cao Y., Neif É.M., Coppens J., Jeppesen E. 2018. Effects of warming and nutrients on the microbial food web in shallow lake mesocosms. European Journal of Protistology, 64, 1–12.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c5968b2a-339b-4ffd-b56f-f6a56081c631
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