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Microfluidics and nanofluidics : theory and selected applications / Clement Kleinstreuer
Resource type: Ressourcentyp: Buch (Online)Book (Online)Publisher number: EB00063528Language: English Publisher: Hoboken, N.J : Wiley, 2014Edition: Online-AusgDescription: Online-Ressource (1 online resource.)ISBN:- 9781306207935
- 1306207932
- 9780470619032
- 9781118418000
- 620.1064
- 629.8042
- TJ853.4.M53
- TJ853
Contents:
Summary: Fluidics originated as the description of pneumatic and hydraulic control systems, where fluids were employed (instead of electric currents) for signal transfer and processing. <i>Microfluidics and Nanofluidics: Theory and Selected Applications</i> offers an accessible, broad-based coverage of the basics through advanced applications of microfluidics and nanofluidics. It is essential reading for upper-level undergraduates and graduate students in engineering and professionals in industryPPN: PPN: 80720630XPackage identifier: Produktsigel: ZDB-26-MYL | ZDB-30-PAD | ZDB-30-PQE
""Title Page""; ""Copyright""; ""Dedication""; ""Preface""; ""Part A: A Review of Essentials in Macrofluidics""; ""Chapter 1: Theory""; ""1.1 Introduction and Overview""; ""1.2 Definitions and Concepts""; ""1.3 Conservation Laws""; ""1.4 Homework Assignments""; ""Chapter 2: Applications""; ""2.1 Internal Fluid Flow""; ""2.2 Porous Medium Flow""; ""2.3 Mixture Flows""; ""2.4 Heat Transfer""; ""2.5 Convection-Diffusion Mass Transfer""; ""2.6 Homework Assignments""; ""References (Part A)""; ""Part B: Microfluidics""; ""Chapter 3: Microchannel Flow Theory""; ""3.1 Introduction""
""3.2 Basic Concepts and Limitations""""3.3 Homework Assignments""; ""Chapter 4: Applications in Microfluidics""; ""4.1 Introduction""; ""4.2 Micropumps and Microchannel Flow""; ""4.3 Micromixing""; ""4.4 Laboratory-on-a-Chip Devices""; ""4.5 Homework Assignments and Course Projects""; ""References (Part B)""; ""Part C: Nanofluidics""; ""Chapter 5: Fluid Flow and Nanofluid Flow in Nanoconduits""; ""5.1 Introduction""; ""5.2 Liquid Flow in Nanoconduits""; ""5.3 Rarefied Gas Flow in Nanochannels""; ""5.4 Homework Assignments and Course Projects""; ""Chapter 6: Applications in Nanofluidics""
""6.1 Introduction""""6.2 Nanoparticle Fabrication""; ""6.3 Forced Convection Cooling with Nanofluids""; ""6.4 Nanodrug Delivery""; ""6.5 Homework Assignments and Course Projects""; ""References (Part C)""; ""Part D: Computer Simulations of Fluid-Particle Mixture Flows""; ""Chapter 7: Modeling and Simulation Aspects""; ""7.1 Introduction""; ""7.2 Mathematical Modeling""; ""7.3 Computer Simulation""; ""Chapter 8: Computational Case Studies""; ""8.1 Introduction""; ""8.2 Model Validation and Physical Insight""; ""8.3 Solid Tumor Targeting with Microspheres""
""8.4 Homework Assignments and Course Projects""""References (Part D)""; ""Appendices""; ""Appendix A""; ""A.1 TENSOR CALCULUS""; ""A.2 DIFFERENTIATION""; ""A.3 INTEGRAL TRANSFORMATIONS""; ""A.4 ORDINARY DIFFERENTIAL EQUATIONS""; ""A.5 TRANSPORT EQUATIONS (CONTINUITY, MOMENTUM, AND HEAT TRANSFER)""; ""Appendix B""; ""B.1 CONVERSION FACTORS""; ""B.2 PROPERTIES""; ""B.3 DRAG COEFFICIENT: (A) Smooth Sphere and (B) An Infinite Cylinder as a Function of Reynolds Number""; ""B.4 MOODY CHART""; ""References (Appendices)""; ""Index""
Cover; Title Page; Copyright; Contents; Preface; Part A: A Review of Essentials in Macrofluidics; Chapter 1 Theory; 1.1 Introduction and Overview; 1.2 Definitions and Concepts; 1.2.1 Definitions; 1.2.2 Flow Field Description; 1.2.3 Flow Field Categorization; 1.2.4 Thermodynamic Properties and Constitutive Equations; 1.3 Conservation Laws; 1.3.1 Derivation Approaches; 1.3.2 Reynolds Transport Theorem; 1.3.2.1 Fluid Mass Conservation in Integral Form; 1.3.2.2 Momentum Conservation in Integral Form; 1.3.2.3 Conservation Laws of Energy and Species Mass
1.3.3 Conservation Equations in Differential Form1.3.3.1 Fluid Mass Conservation; 1.3.3.2 Linear Momentum Conservation; 1.3.3.3 Reduced Forms of the Momentum Equation; 1.3.3.4 Energy and Species Mass Conservation; 1.3.4 Entropy Generation Analysis; 1.4 Homework Assignments; 1.4.1 Physical Insight; 1.4.2 Text Problems; Chapter 2 Applications; 2.1 Internal Fluid Flow; 2.1.1 Problem-Solving Steps; 2.1.2 Sample Solutions of the Reduced Navier-Stokes Equations; 2.2 Porous Medium Flow; 2.3 Mixture Flows; 2.3.1 Introduction; 2.3.2 Modeling Approaches; 2.3.3 Homogeneous Flow Equations
2.3.4 Non-Newtonian Fluid Flow2.3.5 Particle Transport; 2.4 Heat Transfer; 2.4.1 Forced Convection Heat Transfer; 2.4.2 Convection Heat Transfer Coefficient; 2.5 Convection-Diffusion Mass Transfer; 2.5.1 Modeling Approaches; 2.5.2 Compartmental Modeling; 2.6 Homework Assignments; 2.6.1 Definitions, Concepts, and Physical Insight; 2.6.2 Text Problem; 2.6.3 Homework Sets; 2.6.3.1 Homework Set Ia; 2.6.3.2 Homework Set Ib; 2.6.3.3 Homework Set IIa; 2.6.3.4 Homework Set IIb; References (Part A); Part B: Microfluidics; Chapter 3 Microchannel Flow Theory; 3.1 Introduction
3.1.1 Microfluidic System Components3.1.2 Microfluidic System Integration; 3.1.3 Microfluidic System Challenges; 3.2 Basic Concepts and Limitations; 3.2.1 Scaling Laws; 3.2.2 Fluid Properties and Surface Tension Effects; 3.2.3 Wall Slip Velocity and Temperature Jump; 3.2.4 Electrokinetic Phenomena; 3.2.4.1 Electroosmosis; 3.2.4.2 Electrostatics; 3.2.4.3 Electrophoresis; 3.2.4.4 Nernst-Planck Equation; 3.2.5 Magnetohydrodynamics; 3.3 Homework Assignments; 3.3.1 Physical Insight; 3.3.2 Text Problems; Chapter 4 Applications in Microfluidics; 4.1 Introduction; 4.2 Micropumps and Microchannel Flow
4.2.1 Micropumps4.2.2 Liquid Flow in Microchannels; 4.2.3 Gas Flow in Microchannels; 4.3 Micromixing; 4.4 Laboratory-on-a-Chip Devices; 4.4.1 LoC Processing Steps; 4.4.2 LoC Applications; 4.5 Homework Assignments and Course Projects; 4.5.1 Text-related Questions and Tasks; 4.5.2 Set-Up for Course Projects (CPs); References (Part B); Part C: Nanofluidics; Chapter 5 Fluid Flow and Nanofluid Flow in Nanoconduits; 5.1 Introduction; 5.1.1 Overview; 5.1.2 Nanostructures; 5.1.3 Nanothermodynamics; 5.2 Liquid Flow in Nanoconduits; 5.2.1 Introduction and Overview
5.2.2 Nontraditional Simulation Methods
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