Micro- and Nanocroscale Heat Transfer

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Micro- and nanoscale heat transfer has drawn the attention of many researchers due to its importance in many advanced manufacturing and materials processing. The traditional phenomenological laws, such as Fourier’s law of heat conduction, are challenged in the microscale regime because (1) the characteristic lengths of the various heat carriers are comparable to each other and to the characteristic length of the system considered, and/or (2) the characteristic times of the various heat carriers are comparable to the characteristic energy excitation time [1]. Thus, microscale heat transfer can be referred to as heat transfer occurring on both the micro-length and micro-time scales. Microscale heat transfer finds applications in thin film (micro- length scale) as well as ultra-short pulsed laser processing (micro- time scale).
Micro- and nanoscale heat transfer has drawn the attention of many researchers due to its importance in many advanced manufacturing and materials processing. The traditional phenomenological laws, such as Fourier’s law of heat conduction, are challenged in the microscale regime because (1) the characteristic lengths of the various heat carriers are comparable to each other and to the characteristic length of the system considered, and/or (2) the characteristic times of the various heat carriers are comparable to the characteristic energy excitation time [1]. Thus, microscale heat transfer can be referred to as heat transfer occurring on both the micro-length and micro-time scales. Microscale heat transfer finds applications in thin film (micro- length scale) as well as ultra-short pulsed laser processing (micro- time scale).
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:[[Transport Phenomena in Micro- and Nanoscales|Transport phenomena in micro- and nanoscales]], [[Microscale Heat Conduction|microscale heat conduction]], [[Ultrafast Nonequilibrium Phase Change|ultrafast nonequilibrium phase change]], [[Convection in Mincrochannel|convection in microchannel]], and [[micro- and nanoscale radiation]].
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*<b>[[Transport Phenomena in Micro- and Nanoscales]]</b>
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*<b>[[Microscale Heat Conduction]]</b>
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:[[Hyperbolic model]], [[Dual-Phase Lag (DPL) model]], and [[Two-temperature models]].
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*<b>[[Ultrafast Nonequilibrium Phase Change]]</b>
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*<b>[[Convection in Mincrochannel]]</b>
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*<b>[[Micro- and Nanoscale Radiation]]</b>

Revision as of 21:43, 18 April 2009

Micro- and nanoscale heat transfer has drawn the attention of many researchers due to its importance in many advanced manufacturing and materials processing. The traditional phenomenological laws, such as Fourier’s law of heat conduction, are challenged in the microscale regime because (1) the characteristic lengths of the various heat carriers are comparable to each other and to the characteristic length of the system considered, and/or (2) the characteristic times of the various heat carriers are comparable to the characteristic energy excitation time [1]. Thus, microscale heat transfer can be referred to as heat transfer occurring on both the micro-length and micro-time scales. Microscale heat transfer finds applications in thin film (micro- length scale) as well as ultra-short pulsed laser processing (micro- time scale).

Hyperbolic model, Dual-Phase Lag (DPL) model, and Two-temperature models.