Theoretical limits for radiant energy conversion
Theoretical limits for radiant energy conversion
Theoretical limits for radiant energy conversion are dealt with in two categories: i) Those associated with the second law of thermodynamics ii) Those associated with specific energy level schemes (photochemical system). Particular emphasis is placed on the conversion of solar radiation into work although luminescence and laser emission are also discussed. Attention is given to the calculation of the entropy of solar radiation, both using experimental data and a theoretical model. The theoretical model developed uses diluted black-body radiation (D.B.R.) which is introduced in detail here for the first time. In dealing with photochemical limits a kinetic manylevel model is developed including the role of a metastable triplet state in the energy conversion process. Stimulated emission and other terms are included so that the model is valid even in equilibrium conditions. An ideal solar cell model is derived from the photochemical case and acme basic photovoltaic equations are seen to follow directly from photochemical arguments. A detailed study of the spectral distribution of solar radiation is included so that new conclusions concerning meteorological effects are possible. For example limiting efficiencies and optimum solar cell bandgaps are derived for overcast conditions and for operation undersea.
University of Southampton
Tonge, Gary James
4d0e9c72-489d-4e82-89bb-97dc98b5a694
1980
Tonge, Gary James
4d0e9c72-489d-4e82-89bb-97dc98b5a694
Tonge, Gary James
(1980)
Theoretical limits for radiant energy conversion.
University of Southampton, Doctoral Thesis.
Record type:
Thesis
(Doctoral)
Abstract
Theoretical limits for radiant energy conversion are dealt with in two categories: i) Those associated with the second law of thermodynamics ii) Those associated with specific energy level schemes (photochemical system). Particular emphasis is placed on the conversion of solar radiation into work although luminescence and laser emission are also discussed. Attention is given to the calculation of the entropy of solar radiation, both using experimental data and a theoretical model. The theoretical model developed uses diluted black-body radiation (D.B.R.) which is introduced in detail here for the first time. In dealing with photochemical limits a kinetic manylevel model is developed including the role of a metastable triplet state in the energy conversion process. Stimulated emission and other terms are included so that the model is valid even in equilibrium conditions. An ideal solar cell model is derived from the photochemical case and acme basic photovoltaic equations are seen to follow directly from photochemical arguments. A detailed study of the spectral distribution of solar radiation is included so that new conclusions concerning meteorological effects are possible. For example limiting efficiencies and optimum solar cell bandgaps are derived for overcast conditions and for operation undersea.
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Published date: 1980
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Local EPrints ID: 459225
URI: http://eprints.soton.ac.uk/id/eprint/459225
PURE UUID: b20bf64d-48ec-4147-8c5d-ec737ec851e3
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Date deposited: 04 Jul 2022 17:06
Last modified: 23 Jul 2022 00:30
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Author:
Gary James Tonge
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