| Contributors / C. Saltiel ; A. Datta |
| Heat and Mass Transfer in Microwave Processing / J. Seyed-Yagoobi ; J.E. Bryan |
| Enhancement of Heat Transfer and Mass Transport in Single-Phase and Two-Phase Flows With Electrohydrodynamics / S. Kumar ; K. Mitra |
| Microscale Aspect of Thermal Radiation Transport and Laser Applications / J. Taine ; N. Soufiani |
| Gas IR Radiative Properties: From Spectroscopic Data to Approximate Models / H. Muller-Steinhagen,Cooling Water Fouling In Heat Exchangers |
| Heat Transfer from Heat Generating Pools and Particulate Beds / J.H.S. Lee ; M. Berman ; V.K. Dhir |
| Hydrogen Combustion and its Application to Nuclear Reactor Safety Issues / T.G. Theofanous ; D.F. Fletcher |
| Heat Transfer and Fluid Dynamic Aspects of Explosive Melt-Water Interactions / M.M. Pilch |
| M.D. Allen / D.C. Williams |
| Heat Transfer during Direct Containment Heating |
| Subject Index |
| A View of the History of Heat Transfer in Bioengineering / J.C. Chato |
| Mathematical Models of Bioheat Transfer / C.K. Charney |
| Modelling of Bioheat Transfer Processes at High and Low Temperatures / K.R. Diller |
| Temperature Measurements / J.W. Valvano |
| Chapter References |
| Index |
| Heat Transfer and Fluid Dynamics in the Process of Spray Deposition / C.P. Grigoropoulos ; D. Poulikakos ; J.M. Waldvogel ; T.D. Bennett ; J.-R. Ho ; X. Wu ; X. Zhang |
| Heat and Mass Transfer in Pulsed-Laser-InducedPhase Transformations / Y. Jaluria |
| Heat and Mass Transfer in the Extrusion of Non-Newtonian Materials / P.J. Prescott ; F.P. Incropera |
| Convection Heat and Mass Transfer in Alloy Solidification / R.L. Mahajan |
| Transport Phenomena in Chemical Vapor-Deposition Systems |
| Preface |
| Microscales of Turbulent Heat and Mass Transfer / C.Y. Wang ; P. Cheng ; V.S. Arpaci |
| Multiphase Flow and Heat Transfer in Porous Media / E.F.C. Somerscales and A.E. Bergles |
| Enhancement of Heat Transfer and Fouling Mitigation / K.D. Kihm |
| Laser Speckle Photography Techniques Applied for Heat and Mass Transfer Problems / V. Prasad ; H. Zhang ; A. Anselmo |
| Transport Phenomena in Czochralski Crystal Growth Processes |
| Acoustic Wave Induced Flows and Heat Transfer in Gases and Supercritical Fluids / Bakhtier Farouk ; Yiqiang Lin ; Zhiheng Lei |
| Introduction / I: |
| Mechanically Driven Acoustic Waves / A: |
| Thermacoustic Induced Acoustic Waves in Gases / B: |
| Thermoacoustic Waves in Supercritical Fluids / C: |
| Mathematical Model and Numerical Methods / II: |
| OverView |
| Mathmatical Model |
| Numerical Methods |
| Mechanically Driven Acoustic Waves in Gas-Filled Enclosure / III: |
| Overview |
| Flow in an Acoustically Driven Rectangular Enclosure |
| Flows in an Acoustically Driven Cylindrical Enclosure |
| Interactions of Mechanically Driven Acoustic Waves with Heat Transfer in a Rectangular Chamber / D: |
| Numerical Study of Thermally Induced Acoustic Waves in Gases / IV: |
| Thermally Induced Acoustic Waves in Atmospheric and High Pressure Gases |
| Interactions of Thermally Induced Acoustic Waves with Buoyancy Induced Flows: Side-Wall Heated Enclosures |
| Interaction of Thermally Induced Acoustic Waves with Buoyancy Induced Flow Bottom Wall Heated Enclosures |
| Experimental Study of Thermally Induced Acoustic Waves in Gases / V: |
| Experimental Apparatus and Procedure |
| Experimental Results and Discussion |
| Thermally Induced Acoustic Waves in Supercritical Fluids / VI: |
| Equation of State and Thermodynamic Properties of Supercritical Carbon Dioxide |
| Numerical Results for Supercritical Carbon Dioxide |
| Experimental Study of Thermally Induced Acoustic Waves in Supercritical Fluids / VII: |
| Experimental Apparatus and Procedures |
| Summary and Conclusions |
| References |
| Characterization Methods of High-Intensity Focused Ultrasound-Induced Thermal Field / Rupak K. Banerjee ; Subhashish Dasqupta |
| HIFU Free-Field Characterization in Liquid Medium |
| HIFU Thermal Field Characterization in Tissue Medium |
| HIFU Thermal Field Characterization |
| Invasive Method |
| Nonperturbing Method |
| Noninvasive Method |
| Future Direction |
| Improvement in Calculations: Accounting for Boiling, Cavitation, and Nonlinearity |
| Extension of Inverse Heat Transfer Method: Calculation of Intensity and Acoustic Absorptivity |
| Plasma Discharge in Water / Yong Yang ; Alexander Fridman ; Young I. Cho |
| Needs for Plasma Water Treatment |
| Previous Studies on the Plasma Water Treatment |
| Process of Conventional Electrical Breakdown in Water |
| Underwater Plasma Sources |
| Direct Discharges in Liquid |
| Bubble Discharges in Liquid |
| Dynamics of Non-Equilibrium Plasma in Liquid Water |
| Experiment Setup |
| Results and Discussions |
| Analysis of Microsecond Streamer Propagation |
| Electrostatic Model |
| Thermal Mechanism |
| Stability Analysis |
| Application of Spark Discharge for Scale Removal on Filter Membranes |
| Results and Discussion |
| Plasma-Assisted CaC03 Precipitation |
| Results |
| Mechanism Study |
| Application for Mineral Fouling Mitigation in Heat Exchangers |
| X-Ray Diffraction Tests |
| Application for Water Sterilization / VIII: |
| Previous Studies on Plasma-Assisted Water Sterilization |
| Test Methods |
| Results and Effect of Plasma-Induced UV Radiation on Sterilization |
| Final Remarks / IX: |
| Author Index |
| Microgrooved Heat Pipe / B. Suman |
| Brief Overview of Chapter |
| Brief History of Heat Pipes / b: |
| Aim and Scope |
| Heat Pipe |
| Applications of a Micro Heat Pipe / E: |
| Electronic Cooling |
| Human Disease Remedy |
| Spacecraft Thermal Control |
| Solar Energy Conversion |
| Aircraft Temperature Control |
| Fuel Cell Temperature Regulation / F: |
| Steady-State Operation of Micro Heat Pipes |
| Literature Review of Various Steady-State Models |
| Steady-State Experimental Studies |
| Electrohydrodynamically Augmented Micro Heat Pipe |
| Steady-State Sensitivity Analysis |
| Transient Operation of Micro Heat Pipes |
| Transient Models |
| Transient Experimental Study |
| Transient Sensitivity Analysis |
| Operating and Design Parameters |
| Fill Charge |
| Liquid Height |
| Coolant Liquid Temperature |
| Effect of Surface Tension Gradient on a Micro Heat Pipe |
| Friction Factor and Surface Roughness |
| Fabrication of Micro Heat Pipes |
| Performance Factor / G: |
| Design of Microgrooved Heat Pipes |
| Limitations to Heat Transport |
| Conclusions |
| Nomenclature |
| A Review of Heat Transfer in Nanofluids / Sarit K. Das ; Stephen U.S. Choi |
| From Slurries to Nanofluid |
| Nanofluids: Novel Features |
| Synthesis of Nanoparticles |
| Particle Characterization |
| Preparation of Nanofluids |
| Physical Dispersion Technique |
| Chemical Dispersion Method |
| Single-Step Methods |
| Thermal Conductivity Enhancement in Nanofluids |
| Ceramic Nanofluids |
| Metallic Nanofluids |
| Carbon and Polymer Nanotube Nanofluids |
| Temperature Effect |
| Theories on Thermal Conductivity of Nanofluids |
| Convection in Nanofluids / X: |
| Forced Convection in Nanofluids |
| Experimental Works on Convection in Nanofluids |
| Mechanisms in Convection of Suspensions |
| Analytical and Numerical Studies on Convection in NanoFluids |
| Natural Convection in Nanofluids |
| Boiling in Nanofluids / XI: |
| Pool Boiling Heat Transfer at Higher Solid Particle Concentrations |
| Pool Boiling Heat Transfer at Lower Solid Particle Concentrations |
| Studies on CHF in Pool Boiling / XII: |
| Applications of Nanofluids / XIII: |
| Summary and Future Direction of Research / XIV: |
| Pool Boiling Critical Heat Flux in Dielectric Fluids and Nano Fluids / Arik Mehmet |
| Thermo-Fluid Dynamics of Boiling in Microchannels / Sujoy Kumar Saha |
| Fluid Flow and Heat Transfer from circular and non-circular cylinders submerged in non-Newtonian Liquids / Raj P Chhabra |
| Direct Contact Condensation of Steam Jet in a Pool / Chul-Hwa Song |
| Prediction of the Influence of Energetic Chemical Reactions on Forced Convective Heat Transfer / Bo Yu ; Stuart W. Churchill |
| Advances and Outlooks of Heat Transfer Enhancement by Longitudinal Vortex Generators / Ya-Ling He ; Yuwen Zhang |
| List of Contributors |
| Modeling of Multiscale Heat Transfer Systems Using Volume Averaging Theory / Krsto Sbutega ; David Geb ; Ivan Catton1: |
| Theoretical Fundamentals / 2: |
| Applications / 3: |
| Concluding Remarks / 4: |
| Acknowledgments |
| Nucleate Pool Boiling under Reduced Gravity Conditions-Role of Numerical Simulations / Vijay K. Dhir |
| Pool Nucleate Boiling |
| Results of Bubble Dynamics |
| Nucleate Boiling Heat Transfer |
| Friction and Heat Transfer in Liquid and Gas Flows in Micro- and Nanochannels / M. Michael Yovanovich ; Waqar A. Khan5: |
| Characteristic Lengths and Geometry |
| Regular Polygonal Microchannels |
| Elliptical Microchannels |
| Rectangular Microchannels |
| Rectangular Microchannels with Circular and Segment Ends / 6: |
| Circular Segment Microchannels / 7: |
| Circular Sector Microchannels / 8: |
| Rhombic Microchannels / 9: |
| Right Triangular Microchannels / 10: |
| Isosceles Triangular Microchannels / 11: |
| Scalene Triangular Microchannels / 12: |
| Isosceles Trapezoidal Microchannels / 13: |
| Concentric Circular Annular Microchannels / 14: |
| Central Regular Polygonal Cores in Circular Microducts / 15: |
| Central Circular Core in Polygonal Microducts / 16: |
| Rarefied Gas Flows in Circular and Noncircular Microchannels / 17: |
| Closure / 18: |
| A Personal View of 50 Years of Thermal Radiation Heat Transfer Research / John R. Howell |
| Radiation Research |
| Future Research Areas |
| Final Comments |
| Therapeutic Recruitment of Thermoregulation in Humans by Selective Thermal Stimulation along the Spine / Kenneth R. Diller |
| Glabrous Skin Heat Transfer |
| Glabrous Skin as a Physiological Compact Heat Fxchanger |
| Prior Studies of STS in Nonhuman Mammalian and Avian Species |
| STS Studies in Humans |
| STS Devices to Regulate Human Body Core Temperature Effectively |
| Computer Simulation of the Influence of STS on Thermoregulation |
| Acknowledgments of Support and Contributions |
| Conflict of Interest Statement |
| Evolution of Thermal Dosimetry for Application of Hyperthermia to Treat Cancer / Mark W. Dewhirst ; John Abraham ; Benjamin Viglianti |
| Importance of Thermal Dosimetry for Hyperthermia and Thermal Ablation |
| Randomized Phase III Trial Results |
| Principles of Radiation: Thermal Radiation |
| Radiation Heat Transfer |
| Principles of Monte Carlo Methods: Formulation |
| Methods of Solution |
| Special Treatises |
| Applications of the Monte Carlo Method: Two-Dimensional Systems |
| Some Industrial Applications |
| References Applications on Disk |
| List of Variables in Computer Programs |
| Contributors / C. Saltiel ; A. Datta |
| Heat and Mass Transfer in Microwave Processing / J. Seyed-Yagoobi ; J.E. Bryan |
| Enhancement of Heat Transfer and Mass Transport in Single-Phase and Two-Phase Flows With Electrohydrodynamics / S. Kumar ; K. Mitra |
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