| Description |
1 online resource (780 pages) |
| Series |
Mechanical Engineering series |
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Mechanical engineering series (Berlin, Germany)
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| Contents |
Intro -- Preface -- Contents -- List of Symbols -- Dimensionless Parameters -- Greek Symbols -- Subscripts -- 1 Introduction -- 1.1 Limitations of the Macroscopic Formulation -- 1.2 The Length Scales -- 1.3 From Ancient Philosophy to Contemporary Technologies -- 1.3.1 Microelectronics and Information Technology -- 1.3.2 Lasers, Optoelectronics, and Nanophotonics -- 1.3.3 Microfabrication and Nanofabrication -- 1.3.4 Probe and Manipulation of Small Structures -- 1.3.5 Energy Conversion and Storage -- 1.3.6 Biomolecule Imaging and Molecular Electronics |
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1.4 Objectives and Organization of This Book -- References -- 2 Overview of Macroscopic Thermal Sciences -- 2.1 Fundamentals of Thermodynamics -- 2.1.1 The First Law of Thermodynamics -- 2.1.2 Thermodynamic Equilibrium and the Second Law -- 2.1.3 The Third Law of Thermodynamics -- 2.2 Thermodynamic Functions and Properties -- 2.2.1 Thermodynamic Relations -- 2.2.2 The Gibbs Phase Rule -- 2.2.3 Specific Heats -- 2.3 Ideal Gas and Ideal Incompressible Models -- 2.3.1 The Ideal Gas -- 2.3.2 Incompressible Solids and Liquids -- 2.4 Heat Transfer Basics -- 2.4.1 Conduction -- 2.4.2 Convection |
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2.4.3 Radiation -- 2.5 Summary -- Problems -- References -- 3 Elements of Statistical Thermodynamics and Quantum Theory -- 3.1 Statistical Mechanics of Independent Particles -- 3.1.1 Macrostates Versus Microstates -- 3.1.2 Phase Space -- 3.1.3 Quantum Mechanics Considerations -- 3.1.4 Equilibrium Distributions for Different Statistics -- 3.2 Thermodynamic Relations -- 3.2.1 Heat and Work -- 3.2.2 Entropy -- 3.2.3 The Lagrangian Multipliers -- 3.2.4 Entropy at Absolute Zero Temperature -- 3.2.5 Macroscopic Properties in Terms of the Partition Function -- 3.3 Ideal Molecular Gases |
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3.3.1 Monatomic Ideal Gases -- 3.3.2 Maxwell's Velocity Distribution -- 3.3.3 Diatomic and Polyatomic Ideal Gases -- 3.4 Statistical Ensembles and Fluctuations -- 3.5 Basic Quantum Mechanics -- 3.5.1 The Schrödinger Equation -- 3.5.2 A Particle in a Potential Well or a Box -- 3.5.3 A Rigid Rotor -- 3.5.4 Atomic Emission and the Bohr Radius -- 3.5.5 A Harmonic Oscillator -- 3.6 Emission and Absorption of Photons by Molecules or Atoms -- 3.7 Energy, Mass, and Momentum in Terms of Relativity -- 3.8 Summary -- Problems -- References -- 4 Kinetic Theory and Micro/Nanofluidics |
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4.1 Kinetic Description of Dilute Gases -- 4.1.1 Local Average and Flux -- 4.1.2 The Mean Free Path -- 4.2 Transport Equations and Properties of Ideal Gases -- 4.2.1 Shear Force and Viscosity -- 4.2.2 Heat Diffusion -- 4.2.3 Mass Diffusion -- 4.3 Intermolecular Forces -- 4.3.1 Intermolecular Attractive Forces -- 4.3.2 Total Intermolecular Pair Potentials -- 4.4 The Boltzmann Transport Equation -- 4.4.1 Hydrodynamic Equations -- 4.4.2 Fourier's Law and Thermal Conductivity -- 4.5 Micro/Nanofluidics and Heat Transfer -- 4.5.1 The Knudsen Number and Flow Regimes |
| Summary |
This substantially updated and augmented second edition adds over 200 pages of text covering and an array of newer developments in nanoscale thermal transport. In Nano/Microscale Heat Transfer, 2nd edition, Dr. Zhang expands his classroom-proven text to incorporate thermal conductivity spectroscopy, time-domain and frequency-domain thermoreflectance techniques, quantum size effect on specific heat, coherent phonon, minimum thermal conductivity, interface thermal conductance, thermal interface materials, 2D sheet materials and their unique thermal properties, soft materials, first-principles simulation, hyperbolic metamaterials, magnetic polaritons, and new near-field radiation experiments and numerical simulations. Informed by over 12 years use, the authors research experience, and feedback from teaching faculty, the book has been reorganized in many sections and enriched with more examples and homework problems. Solutions for selected problems are also available to qualified faculty via a password-protected website." Substantially updates and augments the widely adopted original edition, adding over 200 pages and many new illustrations; " Incorporates student and faculty feedback from a decade of classroom use; " Elucidates concepts explained with many examples and illustrations; " Supports student application of theory with 300 homework problems; " Maximizes reader understanding of micro/nanoscale thermophysical properties and processes and how to apply them to thermal science and engineering; " Features MATLAB codes for working with size and temperature effects on thermal conductivity, specific heat of nanostructures, thin-film optics, RCWA, and near-field radiation |
| Notes |
4.5.2 Velocity Slip and Temperature Jump |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Print version record |
| Subject |
Heat -- Transmission.
|
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heat transmission.
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Heat -- Transmission
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| Genre/Form |
Electronic books
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| Form |
Electronic book
|
| ISBN |
9783030450397 |
|
3030450392 |
|
9783030450403 |
|
3030450406 |
|
9783030450410 |
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3030450414 |
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