Advances in Heat TransferGeorge A. Greene, Young I. Cho, James P. Hartnett, Avram Bar-Cohen Elsevier, 2006 M10 17 - 668 pages Advances in Heat Transfer fills the information gap between regularly scheduled journals and university level textbooks by providing in-depth review articles over a broader scope than in journals or texts. The articles, which serve as a broad review for experts in the field, will also be of great interest to non-specialists who need to keep up-to- date with the results of the latest research. It is essential reading for all mechanical, chemical and industrial engineers working in the field of heat transfer, graduate schools or industry.
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Contents
Formulation and Thermal Conductivity Prediction | 169 |
Heat and Mass Transfer in Fluids with Nanoparticle Suspensions | 257 |
The Effective Thermal Conductivity of Saturated Porous Media | 377 |
Mesoscale and Microscale PhaseChange Heat Transfer | 461 |
Physics Correlations and Numerical Modeling | 565 |
Author Index | 633 |
647 | |
Other editions - View all
Advances in Heat Transfer, Volume 39 George A. Greene,Young I. Cho,James P. Hartnett,Avram Bar-Cohen No preview available - 2006 |
Common terms and phrases
atoms base fluid boiling boundary Brownian motion bubble cluster bubble dynamics bubble implosion bubble nucleation calculated carbon nanotubes cavitation collapse compression condensation constant convection Copyright correlation D-acetone density effective conductivity effective thermal conductivity electrons equation equilibrium experimental data experiments f ¼ fcc crystal flask flow patterns frequency function gradient HCACF heat flux Heat Mass Transfer heat pipe heat transfer coefficient heater hydraulic diameter impinging jet increase interaction interface investigation layer liquid pressure mass flux Mass Transfer MD simulations mean free path measured method microchannels microheat mode molecular dynamics nanoparticle suspensions nanotubes neutron Nozad nozzle nucleation oscillations packed beds parameter particles phase phonon Phys potential predicted pressure drop pulse radius SBSL shock wave shown in Fig silicon solid solid–fluid conductivity ratio sonofusion sonoluminescence spheres spherical surface tube turbulent two-phase unit cell unitless vector velocity viscosity volume fraction wall Wang
Popular passages
Page 627 - The Effect of Turbulence on Heat Transfer at a Stagnation Point," International Journal of Heat and Mass Transfer, Vol.