Electrons and Electromagnetic Fields in Nanometer-Scale Structures

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This book deals with a topic of vital importance to the design and function of nanodevices. It covers combined systems of electrons and electromagnetic fields at nanometer scales. When the dimensions of an electromagnetic field reach the nanometer scale, it is impossible to determine whether it is an electromagnetic phenomenon or an excited electronic system. This volume covers this interdisciplinary field, with contributions from both the electronic system and electromagnetic areas.

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Nanomaterials and Nanosystems for Biomedical Applications

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“Nanomaterials and Nanosystems for Biomedical Applications” brings together under a single cover various aspects of functional bioengineered materials and nanostructured biomaterials including commonly used implants and sustained release nanodevices. The book includes expert reviews on the advances and current problems associated with the implants and nanodevices along with their applications in medicine, pharmaceutics, cancer therapy, gene transfer and drug delivery. The editor, M. R. Mozafari (PhD), has been working in the field of nanobiotechnology for the past 14 years and has produced more than 60 publications. The book also describes the key research parameters pertaining to major technologies employed in the field. To put it in perspective, all important aspects dealing with the chemistry, physics, biology and engineering of nanostructured biomaterials and their applications in nanobiotechnology are covered.

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Nanoelectronics: Nanowires, Molecular Electronics, and Nanodevices

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Cutting-edge coverage of nanoelectronics—the next-generation microfabrication technology for the semiconductor industry

Nanoelectronics: Nanowires, Molecular Electronics, and Nanodevices address the state of the art in nanoelectronics. The semiconductor industry is undergoing a transition from standard silicon interconnects to novel nanowires that include carbon nanotubes. New exciting opportunities in emerging materials will take system performance beyond that offered by traditional CMOS-based microelectronics. Written by top notch international experts in industry and academia, this detailed guide is a must for anyone serious about nanofabrication possibilities for future technologies.

Nanoelectronics:

• Covers nanodevices and many other emerging device structures needed in future nanotechnologies
• Is written by top industrial experts and key academic professors—the perfect mix of a practical guide and a scientific resource
• Discusses the potential behind new materials such as carbon nanotubes and quantum dots that will carry circuit performance beyond CMOS microelectronics

The latest on nanoelectronics:
Printed Nanowire Arrays for Electronic and Sensor Applications; Microfabrication and Applications of Nanoparticle Doped Conductive Polymers; Carbon Nanotubes as Nano-Electro-Mechanical Actuators; CNT-based IR Sensors; Electrical Properties of Metallic Nanowires for Nanoelectronic Applications; Nanowires for Chemical Sensing; Metal-Oxide Based Nanotubes

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Quantum Mechanics for Nanostructures

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The properties of new nanoscale materials, their fabrication and applications, as well as the operational principles of nanodevices and systems, are solely determined by quantum-mechanical laws and principles. This textbook introduces engineers to quantum mechanics and the world of nanostructures, enabling them to apply the theories to numerous nanostructure problems. The textbook covers the fundamentals of quantum mechanics, including uncertainty relations, the Schrödinger equation, perturbation theory, and tunneling. These are then applied to a quantum dot, the smallest artificial atom, and compared to hydrogen, the smallest atom in nature. Nanoscale objects with higher dimensionality, such as quantum wires and quantum wells, are introduced, as well as nanoscale materials and nanodevices. Numerous examples throughout the text help students to understand the material.

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Physics And Modeling Of Tera- And Nano-Devices

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Physics and Modeling of Tera- and Nano-Devices is a compilation of papers by well-respected researchers working in the field of physics and modeling of novel electronic and optoelectronic devices. The topics covered include devices based on carbon nanotubes, generation and detection of terahertz radiation in semiconductor structures including terahertz plasma oscillations and instabilities, terahertz photomixing in semiconductor heterostructures, spin and microwave-induced phenomena in low-dimensional systems, and various computational aspects of device modeling. Researchers as well as graduate and postgraduate students working in this field will benefit from reading this book.

Contents: Semiconductor Device Scaling: Physics, Transport, and the Role of Nanowires (D K Ferry et al.); Polaronic Effects at the Field Effect Junctions for Unconventional Semiconductors (N Kirova); Cellular Monte Carlo Simulation of High Field Transport in Semiconductor Devices (S M Goodnick & M Saraniti); Nanoelectronic Device Simulation Based on the Wigner Function Formalism (H Kosina); Quantum Simulations of Dual Gate MOSFET Devices: Building and Deploying Community Nanotechnology Software Tools on nanoHUB.org (S Ahmed et al.); Positive Magneto-Resistance in a Point Contact: Possible Manifestation of Interactions (V T Renard et al.); Impact of Intrinsic Parameter Fluctuations in Nano-CMOS Devices on Circuits and Systems (S Roy et al.); HEMT-Based Nanometer Devices Toward Terahertz Era (E Sano & T Otsuji); Plasma Waves in Two-Dimensional Electron Systems and Their Applications (V Ryzhii et al.); Resonant Terahertz Detection Antenna Utilizing Plasma Oscillations in Lateral Schottky Diode (A Satou et al.); Terahertz Polarization Controller Based on Electronic Dispersion Control of 2D Plasmons (T Nishimura & T Otsuji); Higher-Order Plasmon Resonances in GaN-Based Field-Effect Transistor Arrays (V V Popov et al.); Ultra-Highly Sensitive Terahertz Detection Using Carbon-Nanotube Quantum Dots (Y Kawano et al.); Generation of Ultrashort Electron Bunches in Nanostructures by Femtosecond Laser Pulses (A Gladun et al.); Characterization of Voltage-Controlled Oscillator Using RTD Transmission Line (K Narahara et al.); Infrared Quantum-Dot Detectors with Diffusion-Limited Capture (N Vagidov et al.); Magnetoresistance in Fe/MgO/Fe Magentic Tunnel Junctions (N N Beleskii et al.); Modeling and Implementation of Spin-Based Quantum Computation (M E Hawley et al.); Quantum Engineering for Threat Reduction and Homeland Security (G P Berman et al.); Strong Phase Shift Mask Manufacturing Error Impact on the 65nm Poly Line Printability (N Belova).

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