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Table of Contents
Preface; Contents; 1 Fundamentals and Methodologies; 1.1 Introduction; 1.2 Microscale Effects on Heat and Fluid Flow; 1.3 Generalized Integral Transform Technique (GITT); 1.3.1 Total and Partial Transformation Schemes; 1.3.2 The UNIT Algorithm; 1.3.3 Single Domain Formulation; 1.3.4 Eigenvalue Problem Solution; 2 Heat and Fluid Flow in Single Microchannels; 2.1 Transient Slip Flow in Microchannels; 2.2 Steady, Transient, and Periodic Convection with Slip Flow; 2.3 Convection in Electroosmotic Flow; 2.4 Inverse Problem Analysis for Convection in Slip Flow
2.5 Microchannels with Corrugated Walls2.5.1 Flow Analysis via Full Navier
Stokes Equations; 2.5.2 Heat Transfer Analysis with Approximate Velocity Profile; 2.6 Conjugated Heat Transfer in Microchannels; 2.6.1 Parallel-Plates Channel; 2.6.2 Rectangular Channel; 2.7 Microchannels with Arbitrary Cross Section; 2.7.1 Flow Problem; 2.7.2 Heat Transfer Problem; 2.7.3 Test Cases; 3 Heat and Fluid Flow in Microsystems; 3.1 Micro-heat Spreaders; 3.1.1 Experimental Apparatus and Procedure; 3.1.2 Mathematical Formulation and Solution; 3.1.3 Results and Discussion; 3.2 Micro-heat Exchangers
3.2.1 Experimental Apparatus and Procedure3.2.2 Mathematical Formulation and Solution; 3.2.3 Results and Discussion; Bibliography
2.5 Microchannels with Corrugated Walls2.5.1 Flow Analysis via Full Navier
Stokes Equations; 2.5.2 Heat Transfer Analysis with Approximate Velocity Profile; 2.6 Conjugated Heat Transfer in Microchannels; 2.6.1 Parallel-Plates Channel; 2.6.2 Rectangular Channel; 2.7 Microchannels with Arbitrary Cross Section; 2.7.1 Flow Problem; 2.7.2 Heat Transfer Problem; 2.7.3 Test Cases; 3 Heat and Fluid Flow in Microsystems; 3.1 Micro-heat Spreaders; 3.1.1 Experimental Apparatus and Procedure; 3.1.2 Mathematical Formulation and Solution; 3.1.3 Results and Discussion; 3.2 Micro-heat Exchangers
3.2.1 Experimental Apparatus and Procedure3.2.2 Mathematical Formulation and Solution; 3.2.3 Results and Discussion; Bibliography