Thermal transport characteristics of mixed pressure and electro-osmotically driven flow in micro- and nanochannels with joule heating

Journal of Heat Transfer

Volumn 131, Issue 2, 2009, Pages 1-10

  Chen, Chien Hsin ^a  

^a NATIONAL FORMOSA UNIVERSITY   (Taiwan)

Author keywords

Convection heat transfer; Electro osmosis; Joule heating; Microfluidics

Indexed keywords

ANALYTICAL EXPRESSIONS; ANALYTICAL SOLUTIONS; CHANNEL HEIGHT; CONDUCTIVITY VARIATION; CONVECTION HEAT TRANSFER; CONVECTIVE TRANSPORT; DEBYE LENGTH; DIMENSIONLESS VELOCITY; ELECTRIC POTENTIAL FIELDS; ELECTROOSMOTIC FLOW; ENERGY EQUATION; FINITE LENGTH; FLUID PROPERTY; FRICTION FACTORS; GOVERNING SYSTEM; HYDRODYNAMIC CHARACTERISTICS; JOULE HEATING EFFECT; LENGTH SCALE; LOCAL TEMPERATURE; MIXED FLOWS; MOMENTUM TRANSPORTS; NANO CHANNELS; NORMALIZED TEMPERATURE; NUMERICAL SOLUTION; POISEUILLE FLOW; PRESSURE-DRIVEN; PRESSURE-DRIVEN FLOWS; SLUG FLOW; SURFACE HEAT FLUXES; TEMPERATURE-DEPENDENT PROPERTIES; THERMAL CHARACTERISTICS; THERMAL TRANSPORT; TYPICAL VALUES; VARIABLE FLUID PROPERTIES; VELOCITY PROFILES; VELOCITY SCALE; VISCOSITY VARIATIONS; VOLUME FLOW RATE;

ELECTRIC POTENTIAL; ELECTROLYSIS; FLUID DYNAMICS; FLUIDS; FRICTION; HEAT CONVECTION; HEAT EXCHANGERS; HEAT FLUX; HEATING; HYDRODYNAMICS; JOULE HEATING; MICROCHANNELS; MICROFLUIDICS; NANOFLUIDICS; NUMERICAL ANALYSIS; NUSSELT NUMBER; PRESSURE EFFECTS; TEMPERATURE CONTROL; THERMAL CONDUCTIVITY; THERMAL CONDUCTIVITY OF LIQUIDS; THERMOANALYSIS; TRIBOLOGY; VELOCITY; VISCOSITY;

ELECTROOSMOSIS;

EID: 77952937367     PISSN: 00221481     EISSN: 15288943     Source Type: Journal    
DOI: 10.1115/1.2994720     Document Type: Article

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