Abstract
With the advent of computer, modeling and simulation techniques have achieved a new height. To address the various issues related to the model of a system, simulation techniques have become the essential tool where the model represents the best understanding of the proposed system in an abstract way to explain and verify the actions affecting the real-world system. The present paper explores the simulation process in measuring the conductivity of Germanium (Ge) semiconductor and YBCO superconductor by deploying the mathematical model and simulation approach. Mathematical model has been considered as per Callaway et al. [1] in a modified form. Interesting results have been noticed in both the cases as far as the behavior of various scattering strengths involved in the thermal conduction is concerned. Thus, modeling and simulation not only estimates the results but also enables to understand the behavior of terms or components involved in the process.
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References
Callaway, Joseph, Phys. Rev. Vol. 113 (1959) 1046.
Naylor, T.H., Chang, Computer simulation experimentation with models of economic systems, John Wiley and sons, New York (1971).
Osetsky, Yu N. Computer-simulation study of high temperature phase stability in iron, Phys. Rev. B-57, No. 2 (1998) 755–763.
Gairola, R.P., Phys. St. Sol. (b) Vol. 125 (1985) 65.
Bhatt, R.M., Gairola, R.P., Simulation Analysis for Phonon Conductivity of Germanium. In: Chakravarthy, C.R., Patnaik, L.M., Ravi, M.L., Sabapathy, T., (eds.): Harnessing and Managing Knowledge, CSI Publication (2002) 220–223.
Vail, J.M., Emberly, E., Lu, T., Simulation of point defects in high-density lumeinscent crystals: oxygen in barium fluoride, Phys. Rev. B-57, No. 2, (1998).
Choi, Hyo-Sang, Bae, Ok, Kim, Hye-Rim, Park, Kwon-Bae, Switching Properties of a Hybrid Type Superconducting Fault Current Limiter Using YBCO strips, IEEE transaction on applied superconductivity, Vol. 14, No. 3, (2002) 1833–1837.
Teward, L., Wolkhausan, Th., St. Commun., Vol. 70, (1989) 839.
Srinivasan, R., Studies on High Temperature Superconductors, Anant Narlikar (ed): Superconductors, Nova Science Publisher, NY, Vol. 6, (1989) 263.
Shanon, R.F., Simulation: A survey with research suggestions, AIIE Transaction 7(3) (1975).
Law, Avril M. (ed.): Simulation Modeling and Analysis, Tata McGraw Hill, 4th Edition, (2008).
Naylor, T.H. (ed.): Computer simulation experiments with models of economic systems, John Wiley and sons, New York, (1971).
Ravindran, T. R, Sankaranarayana, V., Srinivasan, R. Pramana-J. Physics, Vol. 32, (1992) 109.
Srivastava, G.C., Kumar, Anil, Phys. Rev. B-25 (1982) 2560.
Bardeen, J., Rickayzen, G. Tewordt, L., Phys. Rev., Vol. 113 (1959) 982.
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Bhatt, R.M. (2016). Modeling and Simulation for Conductivity of Germanium and YBCO. In: Lobiyal, D., Mohapatra, D., Nagar, A., Sahoo, M. (eds) Proceedings of the International Conference on Signal, Networks, Computing, and Systems. Lecture Notes in Electrical Engineering, vol 396. Springer, New Delhi. https://doi.org/10.1007/978-81-322-3589-7_33
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DOI: https://doi.org/10.1007/978-81-322-3589-7_33
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