Analysis of temperature dependence on solar energy radiation pattern at different wavelengths

Analysis of temperature dependence on solar energy radiation pattern at different wavelengths

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internalnotes Ahmed, S., Rashid, M. A., Yaakob, S. B., Yusof, A., Saha, N. C. (2014). Performance analysis and study of economic feasibility of biomass coal co fired power system. 2014 IEEE 8th International Power Engineering and Optimization Techniques (PEOCO2014), Langkawi, Malaysia, 24-25 March, 2014, 68-72. Al-Badi, A. H. (2013). Pre-feasibility study of stand-alone hybrid energy systems for applications in eco-houses. International Journal of Sustainable Engineering, 6(1), 48-54. Bentley, R. W. (2002). Global oil & gas depletion: an overview. Energy policy,30(3), 189-205. Dincer, F. (2011). The analysis on photovoltaic electricity generation status, potential and policies of the leading countries in solar energy. Renewable and Sustainable Energy Reviews, 15(1), 713-720. Dresselhaus, M. S., & Thomas, I. L. (2001). Alternative energy technologies. Nature, 414(6861), 332-337. Dwivedi, S., Maulik, K. P., & Mrityunjay, K. (2014). Hybrid power system based on renewable energies: a future for sustainable energy solutions. International Journal of Advanced Trends in Computer Science and Engineering, 3(1),43 – 49. Fara, B. G. M., Ghatas, H.B.G., Amgad, J.S.H.,Noaman, S.T.S. & Daoud, W.W. (2012).PV Solar System with Cooling. Benha University, Egypt. Hepbasli, A. (2008). A key review on exergetic analysis and assessment of renewable energy resources for a sustainable future. Renewable and Sustainable Energy Reviews, 12(3), 593-661. Jwo, C., Chen, S., Chang, H., Su, Y., Chen, J. (2013) Solar energy and clean energy: Trends and developments. International Journal of Photoennergy, 2(2). Khan, M. A., Allemand, C., & Eagar, T. W. (1991). Noncontact temperature measurement. II. Least squares based techniques. Review of scientific instruments, 62(2), 403-409. Mahrane, A., Chikh, M. & Chikouche, A.(2010). Energy management for standalonePV System. Jordan Journal of Mechanical and Industrial Engineering,4 (1),117 – 120. Maugeri, L. (2012). Oil: the next revolution. Belfert Center for Science and International Affairs, Harvard Kennedy School, Cambridge. Mekhilef, S., Safari, A., Mustaffa, W. E. S., Saidur, R., Omar, R., & Younis, M. A. A. (2012). Solar energy in Malaysia: Current state and prospects. Renewable and Sustainable Energy Reviews, 16(1), 386-396. Mor, G. K., Varghese, O. K., Paulose, M., Shankar, K., & Grimes, C. A. (2006). A review on highly ordered, vertically oriented TiO2 nanotube arrays: Fabrication, material properties, and solar energy applications. Solar Energy Materials and Solar Cells, 90(14), 2011-2075. Rashid, M. A., Yusuf, A., Humayun, M. A., Al-Khateeb, A. K. N. M., & Tamaki, S. (2013). Stability analysis of solar cell characteristics above room temperature using indium nitride based quantum dot. American Journal of Applied Sciences, 10(11),1345-1350. Şen, Z. (2004). Solar energy in progress and future research trends. Progress in energy and combustion science, 30(4), 367-416. Sharaf, A. M. &Yang, L. (2005). An efficient photovoltaic DC village electricity scheme using a sliding mode controller. Proceedings of the 2005 IEEE Conference on Control Applications, August 28-31,Toronto, Canada, 1325-1330. Sidhu, K. S. (2007). Non-conventional energy resources. PEC Campus, Punjab State Electricity Board, Chandigarh, India. White, Mary Anne. Properties of materials.38. New York: Oxford University Press, 1999.
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spelling 11309 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=11309 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072 Restricted Document Article Journal UniSZA Unisza unisza image/jpeg inches 96 96 1415 31 31 791 2014-10-28 14:31:01 1415x791 5526-01-FH02-FSTK-14-01564.jpg UniSZA Private Access Analysis of temperature dependence on solar energy radiation pattern at different wavelengths ARPN Journal of Engineering and Applied Sciences This paper presents a theoretical analysis of the effect of atmopharic temperature and the light emission wavelength from the Sun on the solar energy radiation pattern. In this study, we have investigated extensively the radiant emittance phenomena of the solar radiation by using Planck’s law of radiation and the Stephan-Boltzmann’s law. Wavelength dependence of radiant emittance has been analyzed at three different temperatures. We have considered the three different temperatures such as room temperature i.e. 300K, 275K as temperature below room temperature and 325K as the temperature above room temperature. The three different temperatures considered in this present analysis are chosen very close to each other to investigate exactly the effect of wavelength on the radiation pattern of the emitted energy from the Sun due to the small change in temperature. Further the effect of temperature on radiant emittance has also been investigated at three different wavelengths. The three wave lengths considered in our research work are 1.55µm, 1.3µm and 0.89µm respectively. The range of wavelength has been considered within the limit of 0.89µm - 1.55 µm because this range of wavelength corresponds to the energy bandgap of the semiconductor materials from 0.8 eVto 1.4 eV, which are widely used for solar cell fabrication. The investigation of the temperature dependence with maximum wavelength of the radiated energy was carried out up to the black body temperature. Numerical results obtained have been analyzed. It is revealed from the numerical analysis that not only the atmospheric temperature but also the wavelength of the emitted light from the Sun affects the radiation pattern significantly. 9 9 Asian Research Publishing Network Asian Research Publishing Network 1436-1441 Ahmed, S., Rashid, M. A., Yaakob, S. B., Yusof, A., Saha, N. C. (2014). Performance analysis and study of economic feasibility of biomass coal co fired power system. 2014 IEEE 8th International Power Engineering and Optimization Techniques (PEOCO2014), Langkawi, Malaysia, 24-25 March, 2014, 68-72. Al-Badi, A. H. (2013). Pre-feasibility study of stand-alone hybrid energy systems for applications in eco-houses. International Journal of Sustainable Engineering, 6(1), 48-54. Bentley, R. W. (2002). Global oil & gas depletion: an overview. Energy policy,30(3), 189-205. Dincer, F. (2011). The analysis on photovoltaic electricity generation status, potential and policies of the leading countries in solar energy. Renewable and Sustainable Energy Reviews, 15(1), 713-720. Dresselhaus, M. S., & Thomas, I. L. (2001). Alternative energy technologies. Nature, 414(6861), 332-337. Dwivedi, S., Maulik, K. P., & Mrityunjay, K. (2014). Hybrid power system based on renewable energies: a future for sustainable energy solutions. International Journal of Advanced Trends in Computer Science and Engineering, 3(1),43 – 49. Fara, B. G. M., Ghatas, H.B.G., Amgad, J.S.H.,Noaman, S.T.S. & Daoud, W.W. (2012).PV Solar System with Cooling. Benha University, Egypt. Hepbasli, A. (2008). A key review on exergetic analysis and assessment of renewable energy resources for a sustainable future. Renewable and Sustainable Energy Reviews, 12(3), 593-661. Jwo, C., Chen, S., Chang, H., Su, Y., Chen, J. (2013) Solar energy and clean energy: Trends and developments. International Journal of Photoennergy, 2(2). Khan, M. A., Allemand, C., & Eagar, T. W. (1991). Noncontact temperature measurement. II. Least squares based techniques. Review of scientific instruments, 62(2), 403-409. Mahrane, A., Chikh, M. & Chikouche, A.(2010). Energy management for standalonePV System. Jordan Journal of Mechanical and Industrial Engineering,4 (1),117 – 120. Maugeri, L. (2012). Oil: the next revolution. Belfert Center for Science and International Affairs, Harvard Kennedy School, Cambridge. Mekhilef, S., Safari, A., Mustaffa, W. E. S., Saidur, R., Omar, R., & Younis, M. A. A. (2012). Solar energy in Malaysia: Current state and prospects. Renewable and Sustainable Energy Reviews, 16(1), 386-396. Mor, G. K., Varghese, O. K., Paulose, M., Shankar, K., & Grimes, C. A. (2006). A review on highly ordered, vertically oriented TiO2 nanotube arrays: Fabrication, material properties, and solar energy applications. Solar Energy Materials and Solar Cells, 90(14), 2011-2075. Rashid, M. A., Yusuf, A., Humayun, M. A., Al-Khateeb, A. K. N. M., & Tamaki, S. (2013). Stability analysis of solar cell characteristics above room temperature using indium nitride based quantum dot. American Journal of Applied Sciences, 10(11),1345-1350. Şen, Z. (2004). Solar energy in progress and future research trends. Progress in energy and combustion science, 30(4), 367-416. Sharaf, A. M. &Yang, L. (2005). An efficient photovoltaic DC village electricity scheme using a sliding mode controller. Proceedings of the 2005 IEEE Conference on Control Applications, August 28-31,Toronto, Canada, 1325-1330. Sidhu, K. S. (2007). Non-conventional energy resources. PEC Campus, Punjab State Electricity Board, Chandigarh, India. White, Mary Anne. Properties of materials.38. New York: Oxford University Press, 1999.
spellingShingle Analysis of temperature dependence on solar energy radiation pattern at different wavelengths
summary This paper presents a theoretical analysis of the effect of atmopharic temperature and the light emission wavelength from the Sun on the solar energy radiation pattern. In this study, we have investigated extensively the radiant emittance phenomena of the solar radiation by using Planck’s law of radiation and the Stephan-Boltzmann’s law. Wavelength dependence of radiant emittance has been analyzed at three different temperatures. We have considered the three different temperatures such as room temperature i.e. 300K, 275K as temperature below room temperature and 325K as the temperature above room temperature. The three different temperatures considered in this present analysis are chosen very close to each other to investigate exactly the effect of wavelength on the radiation pattern of the emitted energy from the Sun due to the small change in temperature. Further the effect of temperature on radiant emittance has also been investigated at three different wavelengths. The three wave lengths considered in our research work are 1.55µm, 1.3µm and 0.89µm respectively. The range of wavelength has been considered within the limit of 0.89µm - 1.55 µm because this range of wavelength corresponds to the energy bandgap of the semiconductor materials from 0.8 eVto 1.4 eV, which are widely used for solar cell fabrication. The investigation of the temperature dependence with maximum wavelength of the radiated energy was carried out up to the black body temperature. Numerical results obtained have been analyzed. It is revealed from the numerical analysis that not only the atmospheric temperature but also the wavelength of the emitted light from the Sun affects the radiation pattern significantly.
title Analysis of temperature dependence on solar energy radiation pattern at different wavelengths
title_full Analysis of temperature dependence on solar energy radiation pattern at different wavelengths
title_fullStr Analysis of temperature dependence on solar energy radiation pattern at different wavelengths
title_full_unstemmed Analysis of temperature dependence on solar energy radiation pattern at different wavelengths
title_short Analysis of temperature dependence on solar energy radiation pattern at different wavelengths
title_sort analysis of temperature dependence on solar energy radiation pattern at different wavelengths

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