The Fundamentals of Hard and Superhard Nanocomposites and Heterostructures, Stan Veprek, Maritza Veprek-Heijman, Ali S. Argon, and RuiFeng Zhang Determination of Hardness and Modulus of Thin Films, Alexander M. Korsunsky and S.J. Bull Fracture Toughness and Interfacial Adhesion Strength of Thin Films: Indentation and Scratch Experiments and Analysis, Kaiyang Zeng, Kong Boon Yeap, Amit Kumar, and Lei Chen Toughness and Toughening of Hard Nanocomposite Coatings, Huili Wang and Sam Zhang Processing and Mechanical Properties of Hybrid Sol-Gel-Derived Nanocomposite Coatings, Sandor Nemeth Using Nanomechanics to Optimize Coatings for Cutting Tools, B.D. Beake, S.R. Goodes, J.F. Smith, G.S. Fox-Rabinovich, and S.C. Veldhuis Electrolytic Deposition of Nanocomposite Coatings: Processing, Properties, and Applications, Alsayed Abdel Aal Diamond Coatings: The Industrial Perspective, James Chien-Min Sung, Ming-Chi Kan, Jyh-Ming Ting, and Wan-Yu Wu Amorphous Carbon Coatings, Jyh-Ming Ting, Wan-Yu Wu, Sahendra Pal Sharma, James Chien-Min Sung, and Ming-Chi Kan Transition Metal Nitride-Based Nanolayered Multilayer Coatings and Nanocomposite Coatings as Novel Superhard Materials, Harish C. Barshilia, B. Deepthi, and K.S. Rajam Plasma Polymer Films: From Nanoscale Synthesis to Macroscale Functionality, Vladimir Cech Index
Introduction to Nanoengineering, J.F. Maguire and D.B. Mast Thermodynamic and Statistical Foundations of Small Systems Definitions Boundaries for Nanoscience and Technology Some Final Thoughts References SYNTHESIS OF NANOSCALE MATERIALS Design of Nanostructured Materials, D. Banerjee, J. Lao, and Z. Ren Introduction Motivation, Background and Strategies Experimental Set-up Results and Discussion Large Quantity Nanostructures Concluding Remarks Problems, and References Carbon Nanotubes and Bismuth Nanowires, M.S. Dresselhaus, A. Jorio, and O. Rabin Introduction Carbon Nanotubes Bismuth Nanowires Problems Nanobelts and Nanowires of Functional Oxides, X. Wang and Z.L. Wang Introduction The Nanobelt: What is it? Techniques for Growing Nanobelts/Nanowires Growth Mechanisms The Nanobelt Family Ultra-narrow ZnO Nanobelts Mesoporous ZnO Nanowires Patterned Growth of Aligned ZnO Nanowires Selected Applications of Nanobelts Summary Problems, Acknowledgment, and References Advances in Chemical Vapor Deposition of Carbon Nanotubes, V.N. Shanov, A. Miskin, S. Jain, P. He, and M.J. Schulz CVD Technique for Growth of CNT The CVD Growth System Catalyst and Substrate Preparation Growth of CNT Purification of As-Grown CNT Characterization of CNT Advanced Topics and Future Directions for CVD of CNT Conclusions Problems, Acknowledgment, References Self-assembled Au Nanodots in a ZnO Matrix: A Novel Way to Enhance Electrical and Optical Characteristics of ZnO Films, A. Tiwari and J. Narayan Introduction Experimental Procedure Results and Discussion Conclusions Problems, Acknowledgment, References Synthesis of Boron Nitride Nanotubes Using a Ball-Milling and Annealing Method, Y. Chen and J.S. Williams Boron Nitride Nanotubes High-Energy Ball Milling Technique Synthesis of BN nanotubes from Elemental B Synthesis of BN Nanotubes from BN Compounds Formation Mechanism Discussion Conclusions Problems, Acknowledgment, References MANUFACTURING USING NANOSCALE MATERIALS Plasma Deposition of Ultra-Thin Functional Films on Nanoscale Materials, P. He and D. Shi Introduction The Plasma Coating Technique Applications and Characterization Processing and Characterization of Nanocomposite Materials Summary Problems, References Structural Nanocomposites, H. Mahfuz Introduction Matrix Modification Nanophased Filaments Core Modification Summary Problems, References Synthesis and Characterization of Metal-Ceramic Thin-Film Nanocomposites with Improved Mechanical Properties, D. Kumar, J. Sankar, and J. Narayan Introduction Theory of Pulsed Laser Deposition Experimental Procedure Results and Discussion Conclusions Problems, Acknowledgment, References Macroscopic Fibers of Single-Walled Carbon Nanotubes, V.A. Davis and M. Pasquali Introduction Fibers Produced Directly from SWNT Synthesis Electrophoretic Spinning "Conventional" Fiber Spinning Conclusion Problems, Acknowledgment, References Carbon Nanofiber and Carbon Nanotube Polymer/Composite Fibers and Films, H.G. Chae and S. Kumar Introduction Vapor Grown Carbon Nanofiber and Polymer Composite Films Carbon Nanotube Polymer Composite Fibers Aspects of Carbon Nanotube Polymer Composites Polymer Single Wall Carbon Nanotube Applications Concluding Remarks Problems, Acknowledgment, References Surface Patterning Using Self-Assembled Monolayers: A Bottom-Up Approach to the Fabrication of Microdevices, L. Supriya and R.O. Claus Introduction Experimental Procedure Results and Discussion Conclusions and Applications Problems, Acknowledgment, References Enhancement of the Mechanical Strength of Polymer-Based Composites Using Carbon Nanotubes, K.-T.Lau, J. Sankar and D. Hui Introduction Properties of Carbon Nanotubes Fabrication Processes of Nanotube/Polymer Composites Interfacial Bonding Properties of Nanotube/Polymer Composites Concluding Remarks Problems, Acknowledgment, References Nanoscale Intelligent Materials and Structures, Y.Y. Heung, I. Kang, S. Jain, A. Miskin, S. Narasimhadevara, G. Kirkeria, V. Shinde, S. Pammi, S. Datta, P. He, D. Hurd, M.J. Schulz, V.N. Shanov, D. Shi, F.J. Boerio, and M.J. Sundaresan Introduction A Review of Smart Materials Nanotube Geometric Structure Physical Properties of Nanotubes Manufacturing of Nanoscale Hybrid Materials Design of Nanotube Sensors and Actuators Intelligent Machines for Manufacturing, Self-Repair, and Demanufacturing Conclusions Problems, Acknowledgment, References Thermal Properties and Microstructures of Polymer Nanostructured Materials, J.H. Koo and L.A. Pilato Introduction Selection of Nanoparticles Discussion of Results Summary and Conclusions Problems, Acknowledgment, References Manufacturing, Mechanical Characterization, and Modeling of a Pultruded Thermoplastic Nanocomposite, S. Roy, K. Vengadassalam, F. Hussain, and H. Lu Introduction Experimental Procedure Nanocomposite Morphology Results and Discussion of Test Data Mechanical Properties Characterization Summary and Conclusions Problems, Acknowledgment, References MODELING OF NANOSCALE AND NANOSTRUCTURED MATERIALS Nanomechanics, Y.W. Kwon Introduction Static Atomic Model Coupling Atomic and FEA Models Fatigue Analysis at the Atomic Level Heterogeneous Carbon Nanotubes Problems, Acknowledgment, References Continuum and Atomistic Modeling of Thin Films Subjected to Nanoindentation, J.D. Schall, D.W. Brenner, A.D. Kelkar, and R. Gupta Introduction Modeling of Nanoindentation Molecular Dynamics Simulation of Nanoindentation Conclusions, Problems, References Synthesis, Optimization and Characterization of AlN-TiN Thin Film Heterostructures, C.Waters, S.Yarmolenko, J.Sankar, S. Neralla, and A.D. Kelkar Introduction Pulsed Laser Deposition Characterization of Thin Films Performance Evaluation of Thin Films Optimization of Results Conclusions Problems, Acknowledgment, References Polarization in Nanotubes and Nanotubular Structures, M. B. Nardelli, S. M. Nakhmanson, and V. Meunier Introduction Modern Theory of Polarization Computational Details Polarization in Nanotubes Piezoelectricity in Nanotubes Polarization Effects in Nanotubular Structures Conclusions and Future Perspectives Problems, Acknowledgment, References Multiscale Modeling of Stress Localization and Fracture in Nanocrystalline Metallic Materials, V. Yamakov, D.R. Phillips, E. Saether, and E.H. Glaessgen Introduction The Configuration Model The Molecular Dynamics Model Shear Strength of a Grain Boundary FEM Simulation Results and Discussion Concluding Remarks Problems, Acknowledgment, References Modeling of Carbon Nanotube/Polymer Composites, G.M. Odegard Introduction Carbon Nanotube/Polymer Interface Micromechanics Molecular Models Example: SWNT/ Polyimide Composite Example: SWNT/Polyethylene Composite Summary and Conclusions Problems and References An Introduction to Nanoscale, Microscale, and Macroscale Heat Transport: Characterization and Bridging of Space and Time Scales, C. Anderson and K.K. Tamma Introduction Spatial and Temporal Regimes in Heat Conduction Considerations in time heat conduction Considerations in size heat conduction Boltzmann Transport Equation Two Temperature Models Relaxation Time Numerical Illustration-Two Temperature Model and Pulse Laser Heating Numerical Illustration -One Temperature Model and Heat Conduction Model Number Multilayers and Superlattices The Equation of Phonon Radiative Transfer (EPRT) Callaway/Holland's Model Molecular Dynamics Concluding Remarks Problems, Acknowledgment, References
The density functional theory is applied for examining the electronic structure and spectroscopic properties for InP wurtzite molecules and nanocrystals. In this paper we present calculations of the energy gap, bond lengths, IR and Raman spectrum, reduced mass and force constant. The results of the presented work showing that the InP’s energy gap was fluctuated about to experimental bulk energy gap (1.49 eV). Results of spectroscopic properties including IR and Raman spectrum, reduced mass and force constant as a function of frequency were in accordance with the provided experimental results. In addition, the study of the Gibbs free energy proved the stability phase of InP wurtzoids against transition to InP diamondoids structure.
This new volume presents a wealth of practical experience and research on new methodologies and important applications in chemical nanotechnology. It also includes small-scale nanotechnology-related projects that have potential applications in several disciplines of chemistry and nanotechnology. In this book, contributions range from new methods to novel applications of existing methods to gain understanding of the material and/or structural behavior of new and advanced systems. Topics cover computational methods in chemical engineering and chemoinformatics, studies of some of physico-chemical properties of several important nanoalloy clusters, the use of 3D reconstruction of nanofibrous membranes, nanotechnology research for green engineering and sustainability, nanofiltration and carbon nanotubes applications in water treatment, and much more.
Preface S. Li and X.-L. Gao Microdynamics of Phononic Materials M. I. Hussein, M. J. Frazier, and M. H. Abedinnasab Micromechanics of Elastic Metamaterials X. Zhou, X. Liu, and G. Hu Phase Field Approach Micromechanics in Ferroelectric Crystals Y. Su and G. J. Weng Atomic Structure of 180 Ferroelectric Domain Walls in PbTiO3 A. Yavari and A. Angoshtari Micromechanics-based Constitutive Modeling of Chain-Structured Ferromagnetic Particulate Composites H. Yin, L. Z. Sun, and H. Zhang Nonlinear Dynamic Electromechanics in Functionally Graded Piezoelectric Materials Y. Shindo and F. Narita Mechano-electrochemical Mixture Theories for the Multiphase Fluid-Infiltrated Poroelastic Media H. Hatami-Marbini Micromechanics of Nanocomposites with Interface Energy Effects Z. Huang and J. Wang A Surface/Interface Micro-elasticity Formulation Based on Finite-Size Representative Volume Element P.-A. Itty, V. L. Corvec, and S. Li Continuum-Based Modeling of Size Effects in Micro- and Nanostructured Materials R. K. Abu Al-Rub Strain Gradient Solutions of Eshelby-Type Inclusion Problems X.-L. Gao Problems in the Theories of Couple-Stress Elasticity and Dipolar Gradient Elasticity: A Comparison P. A. Gourgiotis and H. G. Georgiadis Solutions to the Periodic Eshelby Inclusion Problem L. Liu Variational Principles, Bounds, and Percolation Thresholds of Composites X. F. Xu Inclusion Clusters in the Archetype-Blending Continuum Theory K. I. Elkhodary, S. Tang, and W. K. Liu Microstructural Characterization of Metals Using Nanoindentation G. Z. Voyiadjis and D. Faghihi A Multiscale Modeling of Multiple Physics X. Wang, J. Li, J. D. Lee, and A. Eskandarian Coarse-Grained Atomistic Simulations of Dislocation and Fracture in Metallic Materials L. Xiong., Q. Deng, and Y. Chen Timescaling in Multiscale Mechanics of Nanowires and Nanocrystalline Materials V. Tomar Modeling and Simulation of Carbon Nanotube-Based Composites and Devices S. Xiao, J. Ni, W. Yang, and C. Nelsen Concurrent Approach to Lattice Dynamics Based on Extended Space-Time Finite Element Method D. Qian and S. Chirputkar Mechanics of Nanoporous Metals A. Giri, J. Tao, M. Kirca, and A. C. To Numerical Characterization of Nanowires Y. T. Gu and H. F. Zhan Molecular Modeling of the Microstructure of Soft Materials: Healing, Memory, and Toughness Mechanisms S. Keten, S. Mishra, and L. Ruiz Intricate Multiscale Mechanical Behavior of Natural Fish-Scale Composites D. Zhu, F. Barthelat, and F. Vernerey Mechanics of Random Fiber Networks R. C. Picu Size-Dependent Probabilistic Damage Micromechanics and Toughening Behavior of Particle-/Fiber-Reinforced Composites J. Woody and K. Yanase Multiscale Asymptotic Expansion Formulations for Heterogeneous Slab and Column Structures with Three-Dimensional Microstructures D. Wang, L. Fang, and P. Xie Computational Overlap Coupling Between Micropolar Elastic Continuum Finite Elements and Elastic Spherical Discrete Elements in One Dimension R. A. Regueiro and B. Yan Nonconcurrent Computational Homogenization of Nonlinear, Stochastic, and Viscoelastic Materials J. Yvonnet, Q.-C. He, E. Monteiro, A. B. Tran, C. Toulemonde, J. Sanahuja, A. Clement, and C. Soize
This volume covers research results in materials science and materials processing technologies in the various branches of the modern industry. This edition will be interesting and useful for many engineers, academicians, and students.
Mechanics of Multiscale Hybrid Nanocomposites provides a practical and application-based investigation of both static and dynamic behaviors of multiscale hybrid nanocomposites. The book outlines how to predict the mechanical behavior and material characteristics of these nanocomposites via two-step micromechanical homogenization techniques performed in an energy-based approach that is incorporated with the strain-displacement relations of shear deformable beam, plate and shell theories. The effects of using various nanofillers are detailed, providing readers with the best methods of improving nanocomposite stiffness. Both numerical (Ritz, Rayleigh-Ritz, etc.) and analytical (Navier, Galerkin, etc.) solution methods are outlined, along with examples and techniques. Demonstrates the influences of carbon nanotube agglomerates and wave phenomena on the constitutive modeling of three-phase hybrid nanocomposites Analyzes nonlinear dynamic characteristics of hybrid nanocomposite systems, as well as how to monitor the system stability via linearization technique Discusses the stability of linear nanocomposite systems subjected to the dispersion of elastic waves and bending loads Outlines how to design three-phase nanocomposite structures for resistance against buckling-mode failure Instructs how to derive the governing equations of continuous systems in both linear and nonlinear regimes in the framework of various types of kinematic shell and plate theories
This book, Petroleum Nanobiotechnology: Modern Applications for a Sustainable Future, explores the unique fusion of biotechnology and nanotechnology as applied to the different sectors of the oil and gas industry. It is a concise resource on the most recent and most up-to-date bottom-up fabrication techniques in petroleum nanobiotechnology, covering the advantages of biofabrication over chemical or physical techniques from the point of being more cost-effective, ecofriendly, biocompatibly superior, and highly stable. The volume covers the important topic of microbial and phytosynthesis of metal and metal oxide nanoparticles. The key applications discussed here include the application of these nanoparticles in different sectors of the oil and gas industry, with special emphasis on antimicrobial applications, reduction of environmental pollutants, and bio-upgrading of petroleum and its fractions. The discussion of each application is augmented with a critical review of the potential for continued development. The book first provides an overview of petroleum microbiology and nanotechnology and proceeds to consider phytosynthesis of metal nanoparticles, microbial synthesis of metal nanoparticles, biosynthesis of metal oxide nanoparticles, nanobiotechnology and mitigation of microbial-influenced corrosion in petroleum industry, applications of nanobiotechnology in petroleum refining, and how nanobiotechnology can be used for petroleum wastewater treatment. This book covers the very important principle of nanobiotechnology as applied in the petroleum industry and how it can be used for: Oil recovery Microbial enhanced oil recovery Petroleum refinery, such as, for example, desulfurization, denitrogenation, demetallization, biotransformation, and bio-upgrading Bioremediation of oil polluted soil and water Mitigation of microbial corrosion and bio-fouling Toxicity of nano-materials and its obstacles upon application Nanobiotechnology in petroleum industry and the 17 goals of sustainable development The advantages of the application of nanobiotechnology in the oil industries are enormous and clearly outweigh any negligible cons. The success can have a huge impact on the exploration, production, refining, mitigation of corrosion, waste management, and economics. This informative volume will be valuable for petroleum engineers and petroleum microbiologists, scientists, and researchers concerned with nanotechnology, environmental pollution, petroleum biotechnology, petroleum microbiology, petroleum refining, and the petroleum industry in general.
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