"Preface The day of nanoparticles and nanofluids has arrived, and the applications of these media are legion. Here, attention is focused on such disparate applications as biomedical, energy conversion, material properties, and fluid flow and heat transfer. The common denominator of the articles which set forth these applications here is numerical quantification, modeling, simulation, and presentation. The first chapter of this volume conveys a broad overview of nanofluid applications, while the second chapter continues the general thermofluids theme and then narrows the focus to biomedical applications. Chapters 3 and 4 deepen the biomedical emphasis. Equally reflective of current technological and societal themes is energy conversion from dispersed forms to more concentrated and utilizable forms, and these issues are treated in Chapters 5 and 6. Basic to the numerical modeling and simulation of any thermofluid process are material properties. Nanofluid properties have been shown to be less predictable and less repeatable than are those of other media that participate in fluid flow and heat transfer. Property issues for nanofluids are set forth in Chapters 6 and 7. The last three chapters each focus on a specific topic in nanofluid flow and heat transfer. Chapter 8 deals with filtration. Microchannel heat transfer has been identified as the preferred means for the thermal management of electronic equipment, and the role of nanofluids as a coolant is discussed in Chapter 9. Natural convection is conventionally regarded as a low heat-transfer coefficient form of convective heat transfer. Potential enhancement of natural convection due to nanoparticles is the focus of Chapter 10"--
Featuring contributions by leading researchers in the field, Nanoparticle Heat Transfer and Fluid Flow explores heat transfer and fluid flow processes in nanomaterials and nanofluids, which are becoming increasingly important across the engineering disciplines. The book covers a wide range, from biomedical and energy conversion applications to materials properties, and addresses aspects that are essential for further progress in the field, including numerical quantification, modeling, simulation, and presentation.
Topics include:
- A broad review of nanofluid applications, including industrial heat transfer, biomedical engineering, electronics, energy conversion, membrane filtration, and automotive
- An overview of thermofluids and their importance in biomedical applications and heat-transfer enhancement
- A deeper look at biomedical applications such as nanoparticle hyperthermia treatments for cancers
- Issues in energy conversion from dispersed forms to more concentrated and utilizable forms
- Issues in nanofluid properties, which are less predictable and less repeatable than those of other media that participate in fluid flow and heat transfer
- Advances in computational fluid dynamic (CFD) modeling of membrane filtration at the microscale
- The role of nanofluids as a coolant in microchannel heat transfer for the thermal management of electronic equipment
- The potential enhancement of natural convection due to nanoparticles
Examining key topics and applications in nanoscale heat transfer and fluid flow, this comprehensive book presents the current state of the art and a view of the future. It offers a valuable resource for experts as well as newcomers interested in developing innovative modeling and numerical simulation in this growing field.
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| Editors |
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| Contributors |
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Chapter 1 Review of Nanofluid Applications |
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Chapter 2 The Role of Nanoparticle Suspensions in Thermo/Fluid and Biomedical Applications |
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Chapter 3 Multiscale Simulation of Nanoparticle Transport in Deformable Tissue during an Infusion Process in Hyperthermia Treatments of Cancers |
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Chapter 4 Superparamagnetic Iron Oxide Nanoparticle Heating: A Basic Tutorial |
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Chapter 5 Light-Induced Energy Conversion in Liquid Nanoparticle Suspensions |
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Chapter 6 Radiative Properties of Micro/Nanoscale Particles in Dispersions for Photothermal Energy Conversion |
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Chapter 7 On the Thermophysical Properties of Suspensions of Highly Anisotropic Nanoparticles with and without Field-Induced Microstructure |
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Chapter 8 Advances in Fluid Dynamic Modeling of Microfiltration Processes |
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Chapter 9 Computational Analysis of Enhanced Cooling Performance and Pressure Drop for Nanofluid Flow in Microchannels |
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249 | (28) |
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Chapter 10 Natural Convection in Nanofluids |
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| Index |
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W.J. Minkowycz is the James P. Hartnett Professor of Mechanical Engineering at the University of Illinois at Chicago. He joined the faculty at UIC in 1966. His primary research interests lie in the numerical modeling of fluid flow and heat transfer problems. Professor Minkowycz is currently the editor-in-chief of the International Journal of Heat and Mass Transfer, Numerical Heat Transfer, and International Communications in Heat and Mass Transfer. He has won numerous awards for his excellence in teaching, research, and service to the heat transfer community.
E.M. Sparrow is a professor of mechanical engineering at the University of Minnesota. He has taught and performed research there since 1959. Prior to that, he worked in industry. He is a member of the National Academy of Engineering, a Max Jakob awardee, and is a Morse Alumni Distinguished Teaching Professor and Institute Professor. He has published more than 750 peer-reviewed articles on a wide variety of topics in heat transfer and fluid flow and has guided the research for 90 Ph.D. degrees and 215 MS degrees.
Dr. John Abraham has worked in the area of thermal sciences for approximately 20 years. His research areas include nanoscale thermal processes, energy production and distribution, climate monitoring, and medical device development. He has approximately 150 journal publications, conference presentations, book chapters, and patents. Dr. Abraham teaches courses in undergraduate and graduate mechanical engineering programs at the University of St. Thomas, in St. Paul, Minnesota.
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