Reprint

Advances in Heat and Mass Transfer in Micro/Nano Systems

Edited by
August 2022
214 pages
  • ISBN978-3-0365-4968-2 (Hardback)
  • ISBN978-3-0365-4967-5 (PDF)

This is a Reprint of the Special Issue Advances in Heat and Mass Transfer in Micro/Nano Systems that was published in

Chemistry & Materials Science
Engineering
Physical Sciences
Summary

The miniaturization of components in mechanical and electronic equipment has been the driving force for the fast development of micro/nanosystems. Heat and mass transfer are crucial processes in such systems, and they have attracted great interest in recent years. Tremendous effort, in terms of theoretical analyses, experimental measurements, numerical simulation, and practical applications, has been devoted to improve our understanding of complex heat and mass transfer processes and behaviors in such micro/nanosystems. This Special Issue is dedicated to showcasing recent advances in heat and mass transfer in micro- and nanosystems, with particular focus on the development of new models and theories, the employment of new experimental techniques, the adoption of new computational methods, and the design of novel micro/nanodevices. Thirteen articles have been published after peer-review evaluations, and these articles cover a wide spectrum of active research in the frontiers of micro/nanosystems.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
Darcy-Forchheimer theory; nonlinear stretching; nanofluid; magnetohydrodynamics; convective conditions; Darcy-Forchheimer theory; carbon nanotubes; nanofluid; magnetohydrodynamics; thermal radiation; porous cavity; wavy channels; nanofluids; forced convection; heat enhancement; pressure drop; mesh model; microfluidic; flow distributions; fluid network; microchannel; nanofluid; heat transfer enhancement; numerical simulation; monodisperse droplet generation; satellite droplets; piezoelectric method; droplet coalescence; lattice Boltzmann method; inertial migration; Poiseuille flow; pulsatile velocity; loop heat pipe; deionized water; two-phase flow; visualization; heat transfer experiment; heat transfer; porous media; pore-scale modeling; boundary condition; thermal conductivity; porosity; conjugate interface; aspect ratio; Maxwell nanofluid; Darcy–Forchheimer model; thermal radiation; chemical reaction; Brownian diffusion; wearable device; microfluidic chip; sweat collecting; heat transfer; microfluidics; liquid metal; measurement; temperature monitoring; PCR; pin-fins; wavy pin-fins channel; performance criterion; pressure drop; friction factor; n/a

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