Hybrid nanofluids :  preparation, characterization and applications / 
edited by Zafar Said. 
 - Amsterdam :  Elsevier,  2022. 
 - 1 online resource (280 pages) 
 - Micro and Nano Technologies .
 - Micro & nano technologies. .
<br/><br/> 6.4.2. Effect of volume fraction. 
<br/><br/>Intro -- Hybrid Nanofluids: Preparation, Characterization and Applications -- Copyright -- Contents -- Contributors -- Preface -- Acknowledgments -- Chapter 1: Introduction to hybrid nanofluids -- 1.1. Introduction -- 1.1.1. Development of nanomaterials and nanofluids -- 1.1.2. Drawbacks of mono nanofluids -- 1.1.3. Development of hybrid nanofluids -- 1.2. Preparation of hybrid nanofluids -- 1.3. Properties of hybrid nanofluids -- 1.3.1. Thermal conductivity -- 1.3.2. Viscosity -- 1.3.3. Density -- 1.3.4. Specific heat capacity -- 1.3.5. Thermal diffusivity 1.3.6. Electrical, magnetic, dielectric -- 1.4. Applications of hybrid nanofluids -- 1.4.1. Electronic cooling -- 1.4.2. Solar collectors -- 1.4.3. Heat exchangers -- 1.4.4. Nuclear PWR -- 1.4.5. Engine cooling -- 1.4.6. Refrigeration -- 1.4.7. Machining -- 1.4.8. Desalination -- 1.5. Challenges and outlook -- 1.6. Conclusion -- References -- Chapter 2: Preparation and stability of hybrid nanofluids -- 2.1. Introduction -- 2.1.1. One-step method -- 2.1.2. Two-step method -- 2.1.3. Comparison of one-step and two-step methods -- 2.2. Stability of nanofluids -- 2.2.1. Stability evaluation methods Sedimentation method -- Centrifugation method -- Zeta potential method -- Spectral absorbance analysis -- Thermal conductivity measurement -- Electron microscopy -- 2.2.2. Stability enhancement methods -- Ultrasonication -- Addition of surfactants -- Surface modification of nanoparticles -- pH change -- 2.3. Challenges and outlook -- 2.4. Summary -- References -- Chapter 3: Thermophysical, electrical, magnetic, and dielectric properties of hybrid nanofluids -- 3.1. Thermophysical properties -- 3.1.1. Thermal conductivity -- 3.1.2. Viscosity of hybrid nanofluids 3.1.3. Specific heat and density of hybrid nanofluids -- 3.1.4. Magnetic property -- 3.1.5. Dielectric property -- 3.2. Conclusion -- Acknowledgments -- References -- Chapter 4: Hydrothermal properties of hybrid nanofluids -- 4.1. Introduction -- 4.2. Surface tension -- 4.3. Friction factor -- 4.4. Pressure drop -- 4.5. Pumping power -- 4.6. Fouling factor of nanofluid -- 4.7. Conclusions and challenges -- Acknowledgments -- References -- Chapter 5: Rheological behavior of hybrid nanofluids -- 5.1. Introduction -- 5.2. Experimental and numerical studies on rheology 5.3. Effects of various parameters on the rheology of hybrid nanofluids -- 5.3.1. Temperature -- 5.3.2. Particle size and shape -- 5.3.3. Volume concentration -- 5.3.4. Other factors -- 5.4. Conclusion and future outlook -- References -- Chapter 6: Radiative transport of hybrid nanofluid -- Subscript -- 6.1. Introduction -- 6.2. Optical properties -- 6.2.1. Rayleigh scattering approximation -- 6.2.2. Maxwell-Garnett approximation -- 6.2.3. Mie scattering approximation -- 6.3. Radiative transfer -- 6.4. Effect of different parameters on optical properties -- 6.4.1. Effect of particle size 
<br/><br/><label>ISBN: </label>0323855717 9780323855716 
<br/><br/><label>Nat. Bib. No.: </label>GBC1I6299  bnb 
<br/><br/><label>Nat. Bib. Agency Control No.: </label>020387563  Uk 
<br/><br/><label>Subjects--Topical Terms: </label><br/>Nanofluids.<br/>Nanofluids--Industrial applications.<br/>Nanofluides.<br/>Nanofluides--Applications industrielles.<br/>Nanofluids.
<br/><br/><label>LC Class. No.: </label>TJ853.4.M53 
<br/><br/><label>Dewey Class. No.: </label>620.106