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http://dx.doi.org/10.1016/j.net.2019.09.018

A novel analytical approach for advection diffusion equation for radionuclide release from an area source  

Esmail, S. (Department of Mathematics and Theoretical Physics, Nuclear Search Center, Atomic Energy Authority)
Agrawal, P. (International Center for Basic and Applied Science)
Aly, Shaban (Department of Mathematics, Faculty of Science, King Khalid University)
Publication Information
Nuclear Engineering and Technology / v.52, no.4, 2020 , pp. 819-826 More about this Journal
Abstract
The method of the Laplace transform has been used to obtain an analytical solution of the three-dimensional steady state advection diffusion equation for the airborne radionuclide release from any nuclear installation such as the power reactor in an area source. The present treatment takes into account the removal of the pollutants through the nuclear reaction. We assume that the pollutants are emitted as a constant rate from the area source. This physical consideration is achieved by assuming that the vertical eddy diffusivity coefficient should be a constant. The prevailing wind speed is a constant in 𝑥- direction and a linear function of the vertical height z. The present model calculations are compared with the other models and the available data of the atmospheric dispersion experiments that were carried out in the nuclear power plant of Angra dos Reis (Brazil). The results show that the present treatment performs well as the analytical dispersion model and there is a good agreement between the values computed by our model and the observed data.
Keywords
The laplace transform method; Three-dimensional steady state advection diffusion equation; The airborne radionuclide release; The hypergeometric function and the eddy diffusivity coefficients;
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  • Reference
1 X. Yang, Y. Yang, C. Cattani, M. Zhu, A new technique for solving the 1-D Burgers equation, Therm. Sci. 21 (2017) S129-S136.
2 D. Assante, C. Cesarano, C. Fornaro, L. Vazquez, Higher order and fractional diffusive equations, J. Eng. Sci. and Tech. Rev. 8 (2015) 202-204.   DOI
3 A. Blackadar, Turbulence and Diffusion in the Atmosphere: Lectures in Environmental Sciences, Springer-Verlag, 1997.
4 R. Biagio, G. Godoy, I. Nicoli, D. Nicolli, P. Thomas, First atmospheric diffusion experiment Campaign at the Angra site. - KfK 3936, Karlsruhe, and CNEN 1201, Rio de Janeiro, 1985.
5 C. Cesarano, C. Fornaro, L. Vazquez, Operational results on bi-orthogonal hermite functions, Acta Math. Univ. Comen. LXXXV (2016) 43-68.
6 N. Lebedev, Special Functions and Their Applications, PRENTICE-HALL, INC., Englewood Cliffs, 1965.
7 D. Buske, M. de Vilhena, B. Bodmann, C. Segatto, T. Tirabassi, A general advection diffusion model for radioactive substance dispersion released from nuclear power plants, in: Int. Conference on Mathematics and Computational Methods Applied to Nuclear Science and Engineering, 2011.
8 I. Gradshteyn, I. Ryzhik, Table of Integrals, Series, and Products, seventh ed., Elsevier Inc., 2007.
9 D. Fox, Judging air quality model performance-a summary of the AMS workshop on dispersion model performance, Bull. Am. Meteorol. Soc. 62 (1981) 599-609.   DOI
10 D. Moreira, T. Tirabassi, M. Vilhena, J. Carvalho, A semi-analytical model for the tritium dispersion simulation in the PBL from the Angra I nuclear power plant, Ecol. Model. 189 (2005) 413-424.   DOI
11 D. Moreira, A. Goulart, P. Soares, M. Vilhena, Dispersion modelling of atmospheric contaminants in the Angra nuclear power plant using LES and a new model for the CBL growth, in: Inter. Nucl. Atlantic Conference-INAC 978, 2009, pp. 3-8.
12 D. Moreira, P. Soares, A. Goulart, M. Vilhena, On the new parameterisation of the eddy diffusivity for radioactive pollutant dispersion, Int. J. Nucl. Energy Sci. Technol. 6 (2011) 166-176.   DOI
13 N. Nieuwstadt, Van Dop, Atmospheric Turbulence and Air Pollution Modelling, D. Reidel Publishing Company, 1982.
14 J. Sorensen, An Assessment of Hermite function based approximations of mutual information applied to independent component analysis, Entropy 10 (2008) 745-756.   DOI
15 G. Walter, Properties of Hermite series estimation of probability density, Ann. Stat. 5 (1977) 1258-1264.   DOI
16 G. Weymar, D. Buske, R. Quadros, G. Gonçalves, Application of a new approach in an analytical model to simulate the dispersion of a radioactive pollutant, Inter. J. Devel. Res. 8 (2018) 24738-24746.
17 G. Weymar, D. Buske, M. Vilhena, B. Bodmann, R. Quadros, An analytical model for radioactive pollutant release simulation in the atmospheric boundary layer, in: Int. Nuclear Atlantic Conference - INAC 24-29, 2011.
18 X. Yang, New integral transforms for solving a steady heat transfer problem, Therm. Sci. 21 (2017) S79-S87.
19 J. Wilson, An approximate analytical solution to the diffusion equation for short-range dispersion from a continuous ground-level source, Boundary-Layer Meteorol. 23 (1982) 85-103.   DOI
20 X. Yang, F. Gaoa, A new technology for solving diffusion and heat equations, Therm. Sci. 21 (2017) 133-140.   DOI