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Analyzing nanofluids suspension using the porous media interface heat transfer model
Peter Vadasz, Peter Vadasz
Mechanical Engineering
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Dive into the research topics of 'Analyzing nanofluids suspension using the porous media interface heat transfer model'. Together they form a unique fingerprint.
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Keyphrases
Porous Media
100%
Nanofluid
100%
Effective Thermal Conductivity
100%
Heat Transfer Model
100%
Interface Heat Transfer Coefficient
100%
Media Interface
100%
Maxwell
50%
Effective Medium Theory
50%
Convection
25%
Heat Transfer Enhancement
25%
Jeffreys
25%
Transient Hot-wire
25%
Spherical Particles
25%
Hyperbolic Heat Conduction
25%
Classical Theory
25%
Davis
25%
Forced Rayleigh Scattering
25%
Higher-order Corrections
25%
Thermal Lensing
25%
Optical Beam Deflection
25%
Brownian Motion
25%
Thermo-optic
25%
Thermal Conductivity Enhancement
25%
Buongiorno
25%
Particle Geometry
25%
Optical Methods
25%
All-optical
25%
Physics
Thermal Conductivity
100%
Nanofluid
100%
Conductive Heat Transfer
20%
Transients
20%
Heat Transfer Enhancement for Application
20%
Rayleigh Scattering
20%
Thermal Lensing
20%
Brownian Motion
20%
Optical Method
20%
Chemical Engineering
Thermal Conductivity
100%
Heat Conduction
20%