Amsterdam : , : Elsevier, , [2015]

©2015

0-323-35381-9

1 online resource (412 p.)

Micro and Nano Technologies

515/.392

Nanofluids

Nonlinear systems

Inglese

Description based upon print version of record.

Front Cover; Application of Nonlinear Systems in Nanomechanics and Nanofluids: Analytical Methods and Applications; Copyright; Dedication ; Contents; Preface; Introduction; Audience; Acknowledgments; Chapter 1: Introduction to Nanotechnology, Nanomechanics, Micromechanics, and Nanofluid; 1.1. Nanotechnology; 1.1.1. Introduction to Nanotechnology; 1.1.2. Origins; 1.1.3. Fundamental Concepts; 1.1.4. Nanomaterials; 1.2. Nanomechanics; 1.3. Micromechanics; 1.4. Nanofluid; 1.4.1. Introduction; 1.4.2. Synthesis of Nanofluids; 1.4.3. Smart Cooling Nanofluids

1.4.4. Response Stimuli Nanofluids for Sensing Applications1.4.5. Applications; References; Chapter 2: Semi Nonlinear Analysis in Carbon Nanotube; 2.1. Introduction of Carbon Nanotube; 2.1.1. Single-Wall Nanotubes; 2.1.2. Multiwall Nanotubes; 2.1.3. Double-Wall Nanotubes; 2.2. Single SWCNT over a Bundle of Nanotube; 2.2.1. Introduction; 2.2.2. Formulations; 2.2.2.1. Schematic of problem; 2.2.2.2. Modeling the individual SWCNT as a beam; 2.2.2.3. Differential quadrature and solution procedure; 2.2.2.4. Finite element method; 2.2.3. Results; 2.2.3.1. Mesh point number effect

2.2.3.2. Length effect2.2.3.3. Validation of GDQ approach; 2.2.4. Conclusion; 2.3. Cantilevered SWCNT as a Nanomechanical Sensor; 2.3.1. Introduction; 2.3.2. Analysis of the Problem; 2.3.2.1. Basic

bending vibration and resonant frequencies of SWCNT with attached mass; 2.3.2.2. Resonant frequency of cantilevered SWCNT where the mass is rigidly attached to the tip; 2.3.3. Numerical Results; 2.3.3.1. Vibration mode analysis; 2.3.4. Mass Sensor Mode Comparison; 2.3.5. Conclusion; 2.4. Nonlinear Vibration for Embedded CNT; 2.4.1. Introduction; 2.4.2. Basic Equations; 2.4.3. Solution Methodology

2.4.4. Numerical Results and Discussion2.4.5. Conclusion; 2.5. Curved SWCNT; 2.5.1. Introduction; 2.5.2. Vibrational Model; 2.5.3. Solution Methodology; 2.5.4. Numerical Results and Discussion; 2.5.5. Conclusion; 2.6. CNT with Rippling Deformations; 2.6.1. Introduction; 2.6.2. Vibration Model; 2.6.2.1. Boundary conditions; 2.6.2.2. Nonlinear vibration model; 2.6.2.3. Nonlinear analysis; 2.6.3. Results and Discussion; 2.6.4. Conclusion; References; Chapter 3: Physical Relationships between Nanoparticle and Nanofluid Flow; 3.1. Turbulent Natural Convection Using Cu/Water Nanofluid

3.1.1. Introduction3.1.2. Numerical Method; 3.1.2.1. Problem statement; 3.1.2.2. LBM; 3.1.2.3. LES method; 3.1.2.4. LBM based on LES model; 3.1.2.5. LBM for nanofluid; 3.1.2.6. Boundary conditions; 3.1.2.6.1. Flow; 3.1.2.6.2. Temperature; 3.1.3. Code Validation and Mesh Results; 3.1.4. Result and Discussion; 3.1.5. Conclusions; 3.2. Heat Transfer of Cu-Water Nanofluid Flow Between Parallel Plates; 3.2.1. Introduction; 3.2.2. Governing Equations; 3.2.3. Analysis of the HPM; 3.2.4. Implementation of the Method; 3.2.5. Results and Discussion; 3.2.6. Conclusion

3.3. Slip Effects on Unsteady Stagnation Point Flow of a Nanofluid over a Stretching Sheet

With Application of Nonlinear Systems in Nanomechanics and Nanofluids the reader gains a deep and practice-oriented understanding of nonlinear systems within areas of nanotechnology application as well as the necessary knowledge enabling the handling of such systems. The book helps readers understand relevant methods and techniques for solving nonlinear problems, and is an invaluable reference for researchers, professionals and PhD students interested in research areas and industries where nanofluidics and dynamic nano-mechanical systems are studied or applied. The book is useful in areas such as nanoelectronics and bionanotechnology, and the underlying framework can also be applied to other problems in various fields of engineering and applied sciences.