Very large radiative transfer over small distances from a black body for thermophotovoltaic applications

The maximum amount of radiated heat intensity which can be transferred from a black body of refractive index D/sub BB/ to an object of refractive index D/sub OBJ/ located a short distance away is shown to be n/sub smaller//sup 2/ times the free space Planck distribution where n/sub smaller/ is the s...

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Bibliographic Details
Published in:IEEE transactions on electron devices 2000-01, Vol.47 (1), p.241-249
Main Authors: Pan, J.L., Choy, H.K.H., Fonstad, C.G.
Format: Article
Language:English
Subjects:
30 DIRECT ENERGY CONVERSION
BLACKBODY RADIATION
Density
Dielectrics
MATHEMATICAL MODELS
Photovoltaic power systems
PLANCK RADIATION FORMULA
RADIANT HEAT TRANSFER
REFRACTIVE INDEX
Refractivity
Spectra
THERMOPHOTOVOLTAIC CONVERTERS
Thermophotovoltaics
Unity
Wavelengths
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Summary:The maximum amount of radiated heat intensity which can be transferred from a black body of refractive index D/sub BB/ to an object of refractive index D/sub OBJ/ located a short distance away is shown to be n/sub smaller//sup 2/ times the free space Planck distribution where n/sub smaller/ is the smaller of n/sub BB/ and n/sub OBJ/, and where n/sub BB/ and n/sub OBJ/ are assumed greater than unity. The implication is that the radiative power spectral density within a thermophotovoltaic cell could be designed to be much greater than the free space Planck distribution. The maximum radiative intensity transferred occurs when the index of the black body matches that of the object at wavelengths where the Planck distribution is sizeable. A simple expression is found for the transferred radiative intensity as a function of the refractive indices of and the distance separating, the black body and the object. This expression is interpreted in terms of the specific black body modes which are evanescent in the space between the black body and the object and which make the largest contribution to the transmission of radiation. The black body, the object, and the region are all modeled as lossless dielectrics.
ISSN:0018-9383
1557-9646
DOI:10.1109/16.817591