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Lal, Mohan, Gangotri, KM. (1401). Innovation for Prospective energy source through Solar Cell. , 7(3), 1095-1103. doi: 10.22059/jser.2022.339342.1239
Mohan Lal; KM Gangotri. "Innovation for Prospective energy source through Solar Cell". , 7, 3, 1401, 1095-1103. doi: 10.22059/jser.2022.339342.1239
Lal, Mohan, Gangotri, KM. (1401). 'Innovation for Prospective energy source through Solar Cell', , 7(3), pp. 1095-1103. doi: 10.22059/jser.2022.339342.1239
Lal, Mohan, Gangotri, KM. Innovation for Prospective energy source through Solar Cell. , 1401; 7(3): 1095-1103. doi: 10.22059/jser.2022.339342.1239

Innovation for Prospective energy source through Solar Cell

Journal of Solar Energy Research
دوره 7، شماره 3، مهر 2022، صفحه 1095-1103    اصل مقاله (735.8 K)
نوع مقاله: Original Article
شناسه دیجیتال (DOI): 10.22059/jser.2022.339342.1239
نویسندگان
Mohan Lal* 1؛ KM Gangotri2
1Solar research energy Laboratory, Department of Chemistry, Jai Narain Vyas University, Jodhpur (Rajasthan) 342001, INDIA
2Department of Chemistry, Jai Narain Vyas University, Jodhpur (Rajasthan) 342001, INDIA
چکیده
Abstract

The object of the research project is to enhance solar energy conversion into electricity and store it through photogalvanic cells. Various parameters were studied in a photogalvanic having D-Xylose+MB+Brij-35+NaLS PGS (photogalvanic system) for solar cell conversion and storage. The photo potential was observed at 684.00 mV for D-Xylose+MB+Brij-35+NaLS PGS for solar cells. The photocurrent was observed at 230.00 A in D-Xylose+MB+Brij-35+NaLS PGS for solar cells. The impact of solar energy was studied by varying the various parameters in PGS for solar energy-based conversion and storage. The D-Xylose+MB+Brij-35+NaLS PGS for solar cell performance was found 110.00 minutes in absence of light. The value of fill factor of the cell () = 0.2810 was observed and the powerpoint of the cell (pp) = 56.23 W was obtained for the solar energy conversion and storage. The mixed surfactants (NaLS+Brij-35) have experimentally proved the efficient system as the desired object of research with special reference to enhancing electrical out and storage of solar energy.
کلیدواژه‌ها
Keywords Solar energy Innovation؛ Energy System؛ Electrical Power؛ Conversion Efficiency؛ Conversion and Storage
مراجع
  1. Rideal, E.K., Williams, E.G., The action of light on the ferrous ferric iodine iodide equilibrium. Journal of Chemical Society Transactions, 1925. 127:258-269.
  2. Rabinowitch, E., The photogalvanic effect I. The photochemical properties of the thionine-iron system. The Journal of Physical Chemistry, 1940. 8:551-559.
  3. Rabinowitch, E., The photogalvanic effect II. The photogalvanic properties of the thionine-iron system. The Journal of Physical Chemistry, 1940. 8:560-566.
  4. Suda, Y., Shimoura,, Y., Sakata, T., Tsubomura H. Photogalvanic effect in the thionine iron system at semiconductor electrodes. The Journal of Physical Chemistry, 1978. 82:268–271.
  5. Murthy, ASN., Dak, AC., Reddy, KS., Photogalvanic effect in riboflavin ethylenediaminetetraacetic acid system. International Journal of Energy Research, 1980. 4:339–343.
  6. Bayer, LS., Erogle, I., Turker, L., Photogalvanic effect in aqueous methylene blue–nickel mesh system: conversion of light into electricity. International Journal of Energy Research, 2001. 25:207–222.
  7. Wildes, PD., Hobart, DR., Lichtin, NN., Hall, DE., Eckert, JA., Sensitization of an iron–thiazine photogalvanic cell to the blue: an improved match to the insulation’s spectrum. Solar Energy, 1977. 19:567–570.
  8. Dixit, NS., Mackay, RA., Microemulsions as photogalvanic cells fluids. The surfactant thionine–iron (II) system. The Journal of Physical Chemistry, 1982. 86:4593–4598.
  9. Albery, WJ., Archer, MD., Optimum efficiency of photogalvanic cells for solar energy conversion. Nature, 1977. 270:399–402.
  10. Memming, R., Solar energy conversion by Photoelectrochemical processes. Electrochimia Acta, 1980. 25:77–88.
  11. Hamdi, ST., Aliwi, SM., The photogalvanic effect of Fe (II)-b-diketonate/thionine system in aqueous acetonitrile. Monatshefte fur Chemie/Chemical Monthly,1996. 127:339-346.
  12. Ameta, SC., Khamesra, S., Lodha, S., Ameta, R., Use of the thionine-EDTA system in photogalvanic cells for solar energy conversion. Journal of Photochemistry and Photobiology A: Chemistry, 1989. 48:81-86.
  13. Ameta, SC., Punjabi, PB., Vardia, J., Madhwani, S., Chaudhary, S., Use of Bromophenol Red-EDTA system for generation of electricity in a photogalvanic cell. Journal of Power Sources, 2006. 159:747-751.
  14. Gangotri, KM., Meena, RC., Meena R., Use of micelles in photogalvanic cells for solar energy conversion and storage: cetyl trimethyl ammonium bromide-glucose-toluidine blue system. Journal of Photochemistry and Photobiology A: Chemistry,1999. 123:93-97.
  15. Lal, C., Use of mixed dyes in a photogalvanic cell for solar energy conversion and storage: EDTA thionine- Azur B system. Journal of Power Sources, 2007. 164:926–930.
  16. Gangotri, KM., Meena, RC., Use of reductant and photosensitizer in photogalvanic cells for solar energy conversion and storage: oxalic acid-methylene blue system. Journal of Photochemistry and Photobiology A: Chemistry, 2001. 141:175-177.
  17. Madhwani, S., Vardia, J., Punjabi, PB., Sharma, VK., Use of fuchsine basic: ethylene-diamine tetra actic acid system in photogalvanic cell for solar energy conversion. Journal of Power and Energy: Part A, 2007. 221:33-39.
  18. Genwa, KR., Genwa, M., Photogalvanic cell: A new approach for green and sustainable chemistry. Solar Energy Materials and Solar Cells, 2008. 92:522-529.
  19. Genwa, KR., Kumar, A., Sonel, A., Photogalvanic solar energy conversion: Study with photosensitizers Toluidine Blue and Malachite Green in presence of NaLS. Applied Energy, 2009. 86:1431-1436.
  20. Gangotri, P., Gangotri, KM., Studies of the micellar effect on photogalvanics: Solar energy conversion and storage–EDTA–safranine O– DSS system. International Journal Energy Research, 2010. 34:1155-1163.
  21. Bhimwal, MK., Gangotri, KM., Bhimwal, MK., A comparison of conversion efficiencies of various sugars as reducing agents for the photosensitizer eosin in the photogalvanic cell. International Journal of Energy Research, 2013. 37:250-258.
  22. Mao, S., Fan, D., Shen, W., Influence of the mixed micelles on the electron transfer reaction [Co(NH3)5Cl]2 ++ [Fe(CN)6]4- Colloids and Surfaces. A: Physicochemical and Engineering Aspects, 2013. 420:103-108.
  23. Thareja, P., Golematis, A., Street, BC., Wagner, JN., Vethamuthu, MS., Hermanson, KD., Influence of Surfactants on the Rheology and Stability of Crystallizing Fatty Acid Pastes. Journal of the American Oil Chemists Society, 2013. 90:273-283.
  24. Molina-Bolivar, JA., Hierrezuelo, JM., Carnero, CR., Energetics of clouding and size effects in non-ionic surfactant mixtures: The influence of alkyl chain length and NaCl addition. Journal of Chemical Thermodynamics, 2013. 57:59-66.
  25. Lee, NM., Lee, BH., Mixed micellizations of TTAB with other surfactants (DTAB, CTAB, Tween-20, Tween-40, and Tween-80). Journal of the Korean Chemical Society, 2012. 56:556-562.
  26. Ageev, AA., Volkov, BA., Kibalov, MS., Kukleva, KK., Correlation between wetting and deterging abilities in mixed surfactant solutions. Fibre Chemistry, 2012. 44:17-20.
  27. Mohan, L., and Gangotri, KM., A Comparative study the performance of photogalvanic cells with mixed surfactant for solar energy conversion and storage: D- Xylose – Methylene Blue system. Research journal of Recent Sciences, 2013. 2(12):19-27.
  28. Gangotri, KM., Lal, M., Study of photogalvanic effect in photogalvanic cell with mixed surfactant for solar energy conversion and storage. Research Journal of Chemical Sciences, 2013. 3(3):20-25.
  29. Lal, M., Gangotri, KM., Study on the Performance of photogalvanic cell with mixed surfactant for solar energy conversion and storage. Research Journal of Recent Sciences, 2013. (isc2012), 76-81.
  30. Rathore, J., Mohan, L., Study of photogalvanic effect in photogalvanic cell containing single surfactant as DSS, Tartrazine as a photosensitizer and EDTA as reductant for solar energy conversion and storage. Research journal of chemistry and environment, 2018. 06:53-57
  31. Mall, C., Tiwari, S., Solanki, PP., Correlation between Photoelectrochemical and Spectrophotometric Study of Dye-Surfactant Combination in Photogalvanic Cell. Applied Solar Energy, 2019. 55(1):18-29. DOI: 10.3103/S0003701X19010092
  1. P, Koli., Pareek RK., Dayma, Y., Jonwal, M., Formic Acid reductant-Sodium Lauryl Sulphate Surfactant enhanced photogalvanic effect of Indigo Carmine dye sensitizer for simultaneous solar energy conversion and storage. Energy Reports, 2021.7(107):3628-3638, DOI: 10.1016/j.egyr.2021.06.022
  1. Jayshree, R., Rakesh Kumar, A., Pratibha, S., Mohan, L., Study of Electrical Output in Photogalvanic Cell for Solar Energy Conversion and Storage: Lauryl Glucoside-Tartrazine-D-Fructose System. Indian Journal of Science and Technology, 2022. 15(23):1159-1165. DOI: 17485/IJST/v15i23.493
  2. Jayshree, R., Rakesh Kumar, A., Pratibha, S., Mohan, L., study of Photogalvanic cell for electrical output in solar energy conversion and storage: single surfactant as lauryl glucoside, Tartrazine as a photosensitizer and D-fructose as reductant, research journal of chemistry and environment, 2022. 26(6):24-29. DOI: 25303/2606rjce024029
  3. Lal, M., Gangotri, KM., Innovation in progressive study for prospective energy source through photo‐galvanic‐system: D‐Xylose+MB+Brij‐35+NaLS. International Journal of Energy Research, 2022. August:1-10 DOI: 10.1002/er.8525
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