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• W2907671641 abstract "The heat equation based on the Fourier heat conduction law is normally used for modelling of thermal phenomena in solids. Unfortunately, this classic theory sometimes fails to predict correctly the evolution of temperature field in time, especially for rapid thermal processes occurring in structures of nanoscale dimensions. Thus, other alternative mathematical models were developed Among them, the dual-phase-lag equation seems to be the most promising candidate for modelling of temperature distribution in such cases. However, there exist virtually no validated methodology to determine experimentally the parameters of this model. The standard resistance thermometry procedures cannot be applied here directly because of the high frequency of signals and small physical dimensions of investigated structures. This problem is illustrated in this paper based on a practical example of the MEMS test structure, for which its electrical and thermal responses to various excitations are presented and analysed in detail. The objective of these analyses is to find the best method to estimate the thermal models parameters for the considered mathematical model." @default.
• W2907671641 created "2019-01-11" @default.
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• W2907671641 date "2018-09-01" @default.
• W2907671641 modified "2023-10-16" @default.
• W2907671641 title "Assessment of Different Methodologies for The Estimation of DPL Model Parameter Values for Dynamic Thermal Simulations of Nanoscale Electronic Structures" @default.
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• W2907671641 doi "https://doi.org/10.1109/therminic.2018.8593289" @default.
• W2907671641 hasPublicationYear "2018" @default.
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