Microfluidics and Nanofluidics : Theory and Selected Applications.

Fluidics originated as the description of pneumatic and hydraulic control systems, where fluids were employed (instead of electric currents) for signal transfer and processing. Microfluidics and Nanofluidics: Theory and Selected Applications offers an accessible, broad-based coverage of the basics t...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Kleinstreuer, C.
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Chichester : Wiley, 2014.
©2014
Temas:
Microfluidics.
Nanofluids.
Microfluidique.
Nanofluides.
SCIENCE > Mechanics > Fluids.
TECHNOLOGY & ENGINEERING > Engineering (General)
Microfluidics
Nanofluids
Acceso en línea:Texto completo

MARC

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100 1 |a Kleinstreuer, C. 
245 1 0 |a Microfluidics and Nanofluidics :  |b Theory and Selected Applications. 
260 |a Chichester :  |b Wiley,  |c 2014. 
264 4 |c ©2014 
300 |a 1 online resource (456 pages) 
336 |a text  |b txt  |2 rdacontent 
337 |a computer  |b c  |2 rdamedia 
338 |a online resource  |b cr  |2 rdacarrier 
588 0 |a Print version record. 
504 |a Includes bibliographical references and index. 
520 |a Fluidics originated as the description of pneumatic and hydraulic control systems, where fluids were employed (instead of electric currents) for signal transfer and processing. Microfluidics and Nanofluidics: Theory and Selected Applications 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 industry. 
505 0 0 |g Machine generated contents note:  |g pt.  |t A REVIEW OF ESSENTIALS IN MACROFLUIDICS --  |g ch. 1  |t Theory --  |g 1.1.  |t Introduction and Overview --  |g 1.2.  |t Definitions and Concepts --  |g 1.2.1.  |t Definitions --  |g 1.2.2.  |t Flow Field Description --  |g 1.2.3.  |t Flow Field Categorization --  |g 1.2.4.  |t Thermodynamic Properties and Constitutive Equations --  |g 1.3.  |t Conservation Laws --  |g 1.3.1.  |t Derivation Approaches --  |g 1.3.2.  |t Reynolds Transport Theorem --  |g 1.3.2.1.  |t Fluid Mass Conservation in Integral Form --  |g 1.3.2.2.  |t Momentum Conservation in Integral Form --  |g 1.3.2.3.  |t Conservation Laws of Energy and Species Mass --  |g 1.3.3.  |t Conservation Equations in Differential Form --  |g 1.3.3.1.  |t Fluid Mass Conservation --  |g 1.3.3.2.  |t Linear Momentum Conservation --  |g 1.3.3.3.  |t Reduced Forms of the Momentum Equation --  |g 1.3.3.4.  |t Energy and Species Mass Conservation --  |g 1.3.4.  |t Entropy Generation Analysis --  |g 1.4.  |t Homework Assignments --  |g 1.4.1.  |t Physical Insight --  |g 1.4.2.  |t Text Problems --  |g ch. 2  |t Applications --  |g 2.1.  |t Internal Fluid Flow --  |g 2.1.1.  |t Problem-Solving Steps --  |g 2.1.2.  |t Sample Solutions of the Reduced Navier-Stokes Equations --  |g 2.2.  |t Porous Medium Flow --  |g 2.3.  |t Mixture Flows --  |g 2.3.1.  |t Introduction --  |g 2.3.2.  |t Modeling Approaches --  |g 2.3.3.  |t Homogeneous Flow Equations --  |g 2.3.4.  |t Non-Newtonian Fluid Flow --  |g 2.3.5.  |t Particle Transport --  |g 2.4.  |t Heat Transfer --  |g 2.4.1.  |t Forced Convection Heat Transfer --  |g 2.4.2.  |t Convection Heat Transfer Coefficient --  |g 2.5.  |t Convection-Diffusion Mass Transfer --  |g 2.5.1.  |t Modeling Approaches --  |g 2.5.2.  |t Compartmental Modeling --  |g 2.6.  |t Homework Assignments --  |g 2.6.1.  |t Definitions, Concepts, and Physical Insight --  |g 2.6.2.  |t Text Problem --  |g 2.6.3.  |t Homework Sets --  |g 2.6.3.1.  |t Homework Set Ia --  |g 2.6.3.2.  |t Homework Set Ib --  |g 2.6.3.3.  |t Homework Set IIa --  |g 2.6.3.4.  |t Homework Set lIb --  |t References (Part A) --  |g pt. B  |t MICROFLUIDICS --  |g ch. 3  |t Microchannel Flow Theory --  |g 3.1.  |t Introduction --  |g 3.1.1.  |t Microfluidic System Components --  |g 3.1.2.  |t Microfluidic System Integration --  |g 3.1.3.  |t Microfluidic System Challenges --  |g 3.2.  |t Basic Concepts and Limitations --  |g 3.2.1.  |t Scaling Laws --  |g 3.2.2.  |t Fluid Properties and Surface Tension Effects --  |g 3.2.3.  |t Wall Slip Velocity and Temperature Jump --  |g 3.2.4.  |t Electrokinetic Phenomena --  |g 3.2.4.1.  |t Electroosmosis --  |g 3.2.4.2.  |t Electrostatics --  |g 3.2.4.3.  |t Electrophoresis --  |g 3.2.4.4.  |t Nernst-Planck Equation --  |g 3.2.5.  |t Magnetohydrodynamics --  |g 3.3.  |t Homework Assignments --  |g 3.3.1.  |t Physical Insight --  |g 3.3.2.  |t Text Problems --  |g ch. 4  |t Applications in Microfluidics --  |g 4.1.  |t Introduction --  |g 4.2.  |t Micropumps and Microchannel Flow --  |g 4.2.1.  |t Micropumps --  |g 4.2.2.  |t Liquid Flow in Microchannels --  |g 4.2.3.  |t Gas Flow in Microchannels --  |g 4.3.  |t Micromixing --  |g 4.4.  |t Laboratory-on-a-Chip Devices --  |g 4.4.1.  |t LoC Processing Steps --  |g 4.4.2.  |t LoC Applications --  |g 4.5.  |t Homework Assignments and Course Projects --  |g 4.5.1.  |t Text-related Questions and Tasks --  |g 4.5.2.  |t Set-Up for Course Projects (CPs) --  |t References (Part B) --  |g pt. C  |t NANOFLUIDICS --  |g ch. 5  |t Fluid Flow and Nanofluid Flow in Nanoconduits --  |g 5.1.  |t Introduction --  |g 5.1.1.  |t Overview --  |g 5.1.2.  |t Nanostructures --  |g 5.1.3.  |t Nanothermodynamics --  |g 5.2.  |t Liquid Flow in Nanoconduits --  |g 5.2.1.  |t Introduction and Overview --  |g 5.2.2.  |t Nontraditional Simulation Methods --  |g 5.2.3.  |t Summary of Nanoscale Phenomena and Descriptive Equations --  |g 5.2.4.  |t Nanochannel Flow Examples --  |g 5.3.  |t Rarefied Gas Flow in Nanochannels --  |g 5.3.1.  |t Overview --  |g 5.3.2.  |t Nanochannel Flow Examples --  |g 5.4.  |t Homework Assignments and Course Projects --  |g 5.4.1.  |t Text-Related Questions and Tasks --  |g 5.4.2.  |t Set-Up for Course Projects --  |g ch. 6  |t Applications in Nanofluidics --  |g 6.1.  |t Introduction --  |g 6.2.  |t Nanoparticle Fabrication --  |g 6.2.1.  |t Metals and Metal Oxides for Cooling --  |g 6.2.2.  |t Drug Carriers in Nanomedicine --  |g 6.3.  |t Forced Convection Cooling with Nanofluids --  |g 6.3.1.  |t Nanofluid Properties --  |g 6.3.2.  |t Thermal Nanofluid Flow --  |g 6.3.3.  |t Friction Factor and Pressure Drop Results --  |g 6.3.4.  |t Convective Heat Transfer --  |g 6.4.  |t Nanodrug Delivery --  |g 6.4.1.  |t Types of Drug-Loaded Nanoparticles --  |g 6.4.2.  |t Mechanisms of Nanodrug Targeting --  |g 6.5.  |t Homework Assignments and Course Projects --  |g 6.5.1.  |t Text-Related Questions and Tasks --  |g 6.5.2.  |t Set-Up for Course Projects --  |t References (Part C) --  |g pt. D  |t COMPUTER SIMULATIONS OF FLUID-PARTICLE MIXTURE FLOWS --  |g ch. 7  |t Modeling and Simulation Aspects --  |g 7.1.  |t Introduction --  |g 7.2.  |t Mathematical Modeling --  |g 7.3.  |t Computer Simulation --  |g 7.3.1.  |t Result Interpretation --  |g 7.3.2.  |t Computational Design Aspects --  |g ch. 8  |t Computational Case Studies --  |g 8.1.  |t Introduction --  |g 8.2.  |t Model Validation and Physical Insight --  |g 8.2.1.  |t Transient Laminar Flow in a Single Bifurcation --  |g 8.2.2.  |t Fluid-Particle Dynamics in a Bifurcation --  |g 8.3.  |t Solid Tumor Targeting with Microspheres --  |g 8.3.1.  |t Direct Targeting Methodology --  |g 8.3.2.  |t Optimal Liver Tumor Targeting Study --  |g 8.4.  |t Homework Assignments and Course Projects --  |g 8.4.1.  |t Mathematical Modeling --  |g 8.4.2.  |t Set-Up for Course Projects --  |t References (Part D) --  |t APPENDICES --  |t Appendix A --  |g A.1.  |t Tensor Calculus --  |g A.1.1.  |t Definitions --  |g A.1.2.  |t Operations with? --  |g A.1.3.  |t Some Tensor Identities --  |g A.2.  |t Differentiation --  |g A.2.1.  |t Differential Time Operators --  |g A.2.2.  |t Total Differential --  |g A.2.3.  |t Truncated Taylor Series Expansions and Binomial Theorem --  |g A.2.4.  |t Hyperbolic Functions --  |g A.3.  |t Integral Transformations --  |g A.3.1.  |t Divergence Theorem --  |g A.3.2.  |t Leibniz Rule --  |g A.3.3.  |t Error Function --  |g A.3.4.  |t Integral Methods --  |g A.4.  |t Ordinary Differential Equations --  |g A.5.  |t Transport Equations (Continuity, Momentum, and Heat Transfer) --  |g A.5.1.  |t Continuity Equation --  |g A.5.2.  |t Equation of Motion (or Linear Momentum Equation) --  |g A.5.3.  |t Momentum Equation for Constant-Property Fluids --  |g A.5.4.  |t Heat Transfer Equation for Constant-Property Fluids --  |g A.5.5.  |t Stresses:? =?[??+(??)tr] and Fluxes: qcond = -k?T --  |g A.5.6.  |t Dissipation Function for Newtonian Fluids --  |t Appendix B --  |g B.1.  |t Conversion Factors --  |g B.2.  |t Properties --  |g B.3.  |t Drag Coefficient: (A) Smooth Sphere and (B) An Infinite Cylinder as a Function of Reynolds Number --  |g B.4.  |t Moody Chart --  |t References (Appendices). 
590 |a ProQuest Ebook Central  |b Ebook Central Academic Complete 
650 0 |a Microfluidics. 
650 0 |a Nanofluids. 
650 6 |a Microfluidique. 
650 6 |a Nanofluides. 
650 7 |a SCIENCE  |x Mechanics  |x Fluids.  |2 bisacsh 
650 7 |a TECHNOLOGY & ENGINEERING  |x Engineering (General)  |2 bisacsh 
650 7 |a Microfluidics  |2 fast 
650 7 |a Nanofluids  |2 fast 
758 |i has work:  |a Microfluidics and nanofluidics (Text)  |1 https://id.oclc.org/worldcat/entity/E39PCGwtBY4kvFC4tvJx8jVCjP  |4 https://id.oclc.org/worldcat/ontology/hasWork 
776 0 8 |i Print version:  |z 9781306207935 
856 4 0 |u https://ebookcentral.uam.elogim.com/lib/uam-ebooks/detail.action?docID=1576672  |z Texto completo 
880 0 0 |6 505-00/(S  |g Machine generated contents note:  |g pt.  |t A REVIEW OF ESSENTIALS IN MACROFLUIDICS --  |g ch. 1  |t Theory --  |g 1.1.  |t Introduction and Overview --  |g 1.2.  |t Definitions and Concepts --  |g 1.2.1.  |t Definitions --  |g 1.2.2.  |t Flow Field Description --  |g 1.2.3.  |t Flow Field Categorization --  |g 1.2.4.  |t Thermodynamic Properties and Constitutive Equations --  |g 1.3.  |t Conservation Laws --  |g 1.3.1.  |t Derivation Approaches --  |g 1.3.2.  |t Reynolds Transport Theorem --  |g 1.3.2.1.  |t Fluid Mass Conservation in Integral Form --  |g 1.3.2.2.  |t Momentum Conservation in Integral Form --  |g 1.3.2.3.  |t Conservation Laws of Energy and Species Mass --  |g 1.3.3.  |t Conservation Equations in Differential Form --  |g 1.3.3.1.  |t Fluid Mass Conservation --  |g 1.3.3.2.  |t Linear Momentum Conservation --  |g 1.3.3.3.  |t Reduced Forms of the Momentum Equation --  |g 1.3.3.4.  |t Energy and Species Mass Conservation --  |g 1.3.4.  |t Entropy Generation Analysis --  |g 1.4.  |t Homework Assignments --  |g 1.4.1.  |t Physical Insight --  |g 1.4.2.  |t Text Problems --  |g ch. 2  |t Applications --  |g 2.1.  |t Internal Fluid Flow --  |g 2.1.1.  |t Problem-Solving Steps --  |g 2.1.2.  |t Sample Solutions of the Reduced Navier-Stokes Equations --  |g 2.2.  |t Porous Medium Flow --  |g 2.3.  |t Mixture Flows --  |g 2.3.1.  |t Introduction --  |g 2.3.2.  |t Modeling Approaches --  |g 2.3.3.  |t Homogeneous Flow Equations --  |g 2.3.4.  |t Non-Newtonian Fluid Flow --  |g 2.3.5.  |t Particle Transport --  |g 2.4.  |t Heat Transfer --  |g 2.4.1.  |t Forced Convection Heat Transfer --  |g 2.4.2.  |t Convection Heat Transfer Coefficient --  |g 2.5.  |t Convection-Diffusion Mass Transfer --  |g 2.5.1.  |t Modeling Approaches --  |g 2.5.2.  |t Compartmental Modeling --  |g 2.6.  |t Homework Assignments --  |g 2.6.1.  |t Definitions, Concepts, and Physical Insight --  |g 2.6.2.  |t Text Problem --  |g 2.6.3.  |t Homework Sets --  |g 2.6.3.1.  |t Homework Set Ia --  |g 2.6.3.2.  |t Homework Set Ib --  |g 2.6.3.3.  |t Homework Set IIa --  |g 2.6.3.4.  |t Homework Set lIb --  |t References (Part A) --  |g pt. B  |t MICROFLUIDICS --  |g ch. 3  |t Microchannel Flow Theory --  |g 3.1.  |t Introduction --  |g 3.1.1.  |t Microfluidic System Components --  |g 3.1.2.  |t Microfluidic System Integration --  |g 3.1.3.  |t Microfluidic System Challenges --  |g 3.2.  |t Basic Concepts and Limitations --  |g 3.2.1.  |t Scaling Laws --  |g 3.2.2.  |t Fluid Properties and Surface Tension Effects --  |g 3.2.3.  |t Wall Slip Velocity and Temperature Jump --  |g 3.2.4.  |t Electrokinetic Phenomena --  |g 3.2.4.1.  |t Electroosmosis --  |g 3.2.4.2.  |t Electrostatics --  |g 3.2.4.3.  |t Electrophoresis --  |g 3.2.4.4.  |t Nernst-Planck Equation --  |g 3.2.5.  |t Magnetohydrodynamics --  |g 3.3.  |t Homework Assignments --  |g 3.3.1.  |t Physical Insight --  |g 3.3.2.  |t Text Problems --  |g ch. 4  |t Applications in Microfluidics --  |g 4.1.  |t Introduction --  |g 4.2.  |t Micropumps and Microchannel Flow --  |g 4.2.1.  |t Micropumps --  |g 4.2.2.  |t Liquid Flow in Microchannels --  |g 4.2.3.  |t Gas Flow in Microchannels --  |g 4.3.  |t Micromixing --  |g 4.4.  |t Laboratory-on-a-Chip Devices --  |g 4.4.1.  |t LoC Processing Steps --  |g 4.4.2.  |t LoC Applications --  |g 4.5.  |t Homework Assignments and Course Projects --  |g 4.5.1.  |t Text-related Questions and Tasks --  |g 4.5.2.  |t Set-Up for Course Projects (CPs) --  |t References (Part B) --  |g pt. C  |t NANOFLUIDICS --  |g ch. 5  |t Fluid Flow and Nanofluid Flow in Nanoconduits --  |g 5.1.  |t Introduction --  |g 5.1.1.  |t Overview --  |g 5.1.2.  |t Nanostructures --  |g 5.1.3.  |t Nanothermodynamics --  |g 5.2.  |t Liquid Flow in Nanoconduits --  |g 5.2.1.  |t Introduction and Overview --  |g 5.2.2.  |t Nontraditional Simulation Methods --  |g 5.2.3.  |t Summary of Nanoscale Phenomena and Descriptive Equations --  |g 5.2.4.  |t Nanochannel Flow Examples --  |g 5.3.  |t Rarefied Gas Flow in Nanochannels --  |g 5.3.1.  |t Overview --  |g 5.3.2.  |t Nanochannel Flow Examples --  |g 5.4.  |t Homework Assignments and Course Projects --  |g 5.4.1.  |t Text-Related Questions and Tasks --  |g 5.4.2.  |t Set-Up for Course Projects --  |g ch. 6  |t Applications in Nanofluidics --  |g 6.1.  |t Introduction --  |g 6.2.  |t Nanoparticle Fabrication --  |g 6.2.1.  |t Metals and Metal Oxides for Cooling --  |g 6.2.2.  |t Drug Carriers in Nanomedicine --  |g 6.3.  |t Forced Convection Cooling with Nanofluids --  |g 6.3.1.  |t Nanofluid Properties --  |g 6.3.2.  |t Thermal Nanofluid Flow --  |g 6.3.3.  |t Friction Factor and Pressure Drop Results --  |g 6.3.4.  |t Convective Heat Transfer --  |g 6.4.  |t Nanodrug Delivery --  |g 6.4.1.  |t Types of Drug-Loaded Nanoparticles --  |g 6.4.2.  |t Mechanisms of Nanodrug Targeting --  |g 6.5.  |t Homework Assignments and Course Projects --  |g 6.5.1.  |t Text-Related Questions and Tasks --  |g 6.5.2.  |t Set-Up for Course Projects --  |t References (Part C) --  |g pt. D  |t COMPUTER SIMULATIONS OF FLUID-PARTICLE MIXTURE FLOWS --  |g ch. 7  |t Modeling and Simulation Aspects --  |g 7.1.  |t Introduction --  |g 7.2.  |t Mathematical Modeling --  |g 7.3.  |t Computer Simulation --  |g 7.3.1.  |t Result Interpretation --  |g 7.3.2.  |t Computational Design Aspects --  |g ch. 8  |t Computational Case Studies --  |g 8.1.  |t Introduction --  |g 8.2.  |t Model Validation and Physical Insight --  |g 8.2.1.  |t Transient Laminar Flow in a Single Bifurcation --  |g 8.2.2.  |t Fluid-Particle Dynamics in a Bifurcation --  |g 8.3.  |t Solid Tumor Targeting with Microspheres --  |g 8.3.1.  |t Direct Targeting Methodology --  |g 8.3.2.  |t Optimal Liver Tumor Targeting Study --  |g 8.4.  |t Homework Assignments and Course Projects --  |g 8.4.1.  |t Mathematical Modeling --  |g 8.4.2.  |t Set-Up for Course Projects --  |t References (Part D) --  |t APPENDICES --  |t Appendix A --  |g A.1.  |t Tensor Calculus --  |g A.1.1.  |t Definitions --  |g A.1.2.  |t Operations with δ --  |g A.1.3.  |t Some Tensor Identities --  |g A.2.  |t Differentiation --  |g A.2.1.  |t Differential Time Operators --  |g A.2.2.  |t Total Differential --  |g A.2.3.  |t Truncated Taylor Series Expansions and Binomial Theorem --  |g A.2.4.  |t Hyperbolic Functions --  |g A.3.  |t Integral Transformations --  |g A.3.1.  |t Divergence Theorem --  |g A.3.2.  |t Leibniz Rule --  |g A.3.3.  |t Error Function --  |g A.3.4.  |t Integral Methods --  |g A.4.  |t Ordinary Differential Equations --  |g A.5.  |t Transport Equations (Continuity, Momentum, and Heat Transfer) --  |g A.5.1.  |t Continuity Equation --  |g A.5.2.  |t Equation of Motion (or Linear Momentum Equation) --  |g A.5.3.  |t Momentum Equation for Constant-Property Fluids --  |g A.5.4.  |t Heat Transfer Equation for Constant-Property Fluids --  |g A.5.5.  |t Stresses: τ = μ[δν+(δν)tr] and Fluxes: qcond = -kδT --  |g A.5.6.  |t Dissipation Function for Newtonian Fluids --  |t Appendix B --  |g B.1.  |t Conversion Factors --  |g B.2.  |t Properties --  |g B.3.  |t Drag Coefficient: (A) Smooth Sphere and (B) An Infinite Cylinder as a Function of Reynolds Number --  |g B.4.  |t Moody Chart --  |t References (Appendices). 
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