References
- Albery, W. J., and Archer, M. D. 1977. Optimum efficiency of photogalvanic cells for solar energy conversion. Nature 270:399–402.
- Balzani, V., Credi, A., and Venturi, M. 2008. Photochemical conversion of solar energy. ChemSus Chem. 1:26–58.
- Kim, H., Shin, M., Park, J., and Kim, Y. 2010. Initial performance changes of polymer/fullerene solar cells by short-time exposure to simulated solar light. ChemSus Chem. 3:476–480.
- Koli, P. 2014a. Solar energy conversion and storage using Naphthol Green B dye photosensitizer in Photogalvanic cells. Appl. Solar Energy 50:67–73.
- Koli, P. 2014b. Photogalvanic cells: Comparative study of various synthetic dye and natural photo sensitizer present in spinach extract. RSC Adv. 4:46194–46202.
- Koli, P. 2014c. Solar energy conversion and storage: Fast Green FCF- Fructose Photogalvanic cell. Appl. Energy 118:231–237.
- Koli, P. 2015. Study of enhanced Photogalvanic effect of Naphthol Green B in natural sunlight. J. Power Sources 285:310–317.
- Koli, P. 2016. Sodium lauryl sulphate enhanced solar energy conversion by photogalvanic effect of Rhodamine B–Fructose in artificial light. Chem. Select. 1:4624–4629.
- Koli, P., and Sharma, U. 2016. Energy conversion in electrolyte under artificial light: Fast Green FCF–Fructose-Surfactant- small Pt electrode photogalvanic cell. Appl. Solar Energy 52:76–83.
- Koli, P., Sharma, U., and Gangotri, K. M. 2012. Solar energy conversion and storage: Rhodamine B - Fructose photogalvanic cell. Renewable Energy 37:250–258.
- Kuznetsov, V., and Edwards, P. 2010. Functional materials for sustainable energy technologies: Four case studies. ChemSusChem. 3:44–58.
- Lal, M., and Gangotri, K. M. 2015. The optimum conversion efficiency in nile blue arabinose system by photogalvanic cell. Adv. Energy Res. 3:143–155.
- Liu, J., Cao, G., Yang, Z., Wang, D., Dubois, D., Zhou. Zhou, X., Pederson, L., and Zhang, J. G. 2010. Oriented nanostructures for energy conversion and storage. ChemSusChem. 1:676–697.
- Madhwani, S., Ameta, R., Vardia, J., Punjabi, P. B., and Sharma,V. K. 2007. Use of Fluoroscein- EDTA system in photogalvanic cell for solar energy conversion. Energy Sources Part A. 29:721–729.
- Nenival, N. R., and Gangotri, K. M. 2014. A study on the effect of a surfactant in a photosensitizer for solar energy conversion and storage. Energy Sources Part A 36:1484–1490.
- Pramila, S., and Gangotri, K. M. 2007. Use of anionic micelles in photogalvanic cells for solar energy conversion and storage dioctylsulfosuccinate-mannitol-safranine system. Energy Sources Part A 29:1253–1257.
- Sharma, U., Koli, P., and Gangotri, K. M. 2011. Brilliant cresyl blue-fructose for enhancement of solar energy conversion and storage capacity of photogalvanic solar cells. Fuel 90:3336–3342.
- Shiroishi, H., Yuuki, K., Michiko, S., Takayuki, H., Tomoyo, N., Sumio, T., and Masao, K. 2002.Virtual device simulator of bipolar photogalvanic cell. J. Chem. Software. 8:47–54.
- Yu, J., Fan, J., and Zhao, L. 2010 Dye-sensitized solar cells based on hollow anatase TiO2 spheres prepared by self-transformation method. Electrochim. Acta. 55:597–602.
- Tamilarasan, R., and Natarajan, P. 1981. Photovoltaic conversion by macromolecular thionine films. Nature 292:224–225.