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This article is cited in 2 scientific papers (total in 2 papers)
Mathematical modeling and computer science
Mathematical modeling of heat transfer in the film-substrate-thermostat system during heating of an electrically conductive film by a high-density pulse current
N. D. Kuzmichev, M. A. Vasyutin, E. V. Danilova, E. A. Lapshina Ogarev Mordovia State University, Saransk
Abstract:
Mathematical modeling of heat transfer in the film-substrate-thermostat system with a pulsed flow of high-density current through an electrically conductive film has been carried out. On the basis of the simulation, the analysis of the heating of a niobium nitride film with a high resistivity near the critical temperature of the transition to the superconducting state is made. The inhomogeneous heat conduction equation which is solved numerically, simulates heat transfer in the film-substrate-thermostat system for the third on the left and the first on the right initial boundary value problem. Using the symmetry of the problem, the parameter $H$ is determined, which is equal to the ratio of the heat transfer of the film surface to its thermal conductivity; this parameter is necessary for effective heat removal. It is shown that effective heat removal from films can be provided by current-carrying and potential clamping contacts made, for example, of beryllium bronze. This makes possible to study the current-voltage characteristics of superconductors near the critical transition temperature to the superconducting state with high-density currents $(10^4 - 10^5 A/cm^2)$ without significant heating of the samples.
Keywords:
inhomogeneous heat conduction equation, 1st initial-boundary value problem, 3rd initial-boundary value problem, niobium nitride membrane, pulsed heating by current.
Citation:
N. D. Kuzmichev, M. A. Vasyutin, E. V. Danilova, E. A. Lapshina, “Mathematical modeling of heat transfer in the film-substrate-thermostat system during heating of an electrically conductive film by a high-density pulse current”, Zhurnal SVMO, 23:1 (2021), 82–90
Linking options:
https://www.mathnet.ru/eng/svmo791 https://www.mathnet.ru/eng/svmo/v23/i1/p82
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Abstract page: | 117 | Full-text PDF : | 48 | References: | 27 |
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