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• 1 Theoretical Atto-nano Physics
• M. F. Ciappina and M. Lewenstein
• 2 The de Broglie Wave Nature of Molecules, Clusters and Nanoparticles
• Stefan Gerlich, Stefan Kuhn, Armin Shayeghi, and Markus Arndt
• 3 Electromagnetic Nanonetworks
• Md. Humaun Kabir and Kyung Sup Kwak
• 4 Nanoscale Energy Transport
• Jafar Ghazanfarian, Zahra Shomali and Shiyun Xiong
• 5 Coulomb Effects and Exotic Charge Transport in Nanostructured Materials
• Monique Tie and Al-Amin Dhirani
• 6 Spin-Dependent Thermoelectric Currents in Nanostructures (Tunnel Junctions, Thin Films, Small Rings and Quantum Dots)
• K.H. Bennemann
• 7 Joule Heat Generation by Electric Current in Nanostructures
• S. V. Gantsevich and V. L. Gurevich
• 8 Quantum Transport Simulations of Nano-systems: An Introduction to the Green's
• Function Approach
• Andrea Droghetti and Ivan Rungger
• 9 Transient Quantum Transport in Nanostructures
• Pei-Yun Yang, Yu-Wei Huang, and Wei-Min Zhang
• 10 Thermal Transport in Nanofilms
• Yu-Chao Hua, Dao-Sheng Tang, and Bing-Yang Cao
• 11 Thermal Transport and Phonon Coherence in Phononic Nanostructures
• Juan Sebastian Reparaz and Markus R. Wagner
• 12 Quantum Chaotic Systems and Random Matrix Theory
• Akhilesh Pandey, Avanish Kumar, and Sanjay Puri
• 13 Topological Constraint Theory and Rigidity of Glasses
• Mathieu Bauchy
• 14 Topological Descriptors of Carbon Nanostructures
• Sakander Hayat
• 15 Numerical Methods for Large-Scale Electronic State Calculation on Supercomputer
• Takeo Hoshi, Yusaku Yamamoto, Tomohiro Sogabe, Kohei Shimamura, Fuyuki Shimojo,
• Aiichiro Nakano, Rajiv Kalia, and Priya Vashishta
• 16 Atomistic Simulation of Disordered Nano-electronics
• Youqi Ke
• 17 Ab Initio Simulations of Carboxylated Nanomaterials
• Vivian Machado de Menezes and Ivi Valentini Lara
• 18 Phase Behavior of Atomic and Molecular Nanosystems
• R. Stephen Berry
• 19 Exact solutions in the Density Functional Theory (DFT) and Time-Dependent DFT of
• Mesoscopic Systems
• Vladimir U. Nazarov
• 20 Molecular Simulation of Porous Graphene
• Ziqi Tian, Haoran Guo, Liang Chen, and Chad Priest
• 21 Metallic Nanoglasses Investigated by Molecular Dynamics Simulations
• D. Sopu and O. Adjaoud.
• (source: Nielsen Book Data)

• High-Temperature Scanning Probe Microscopy - Fang Low Temperature Investigation of Magnetic Molecules by Scanning Probe Microscopies- Mannini Ultrafast Optical Pump-Probe Scanning Probe Microscopy/Spectroscopy- Shigekawa Triggering Chemical Reactions by Scanning Tunneling Microscopy- Elemans The Circular Mode AFM: A New Experimental Approach for Investigating Nanotribology - Noel & Mazeran Chemical Imaging with Fluorescent Nanosensors -Kruss Nanometer-Scale and Low-Density Imaging with Extreme Ultraviolet and Soft X-Ray Radiation -Wachulak X-Ray Imaging of Single Nanoparticles and Nanostructures -Rolles Helium Ion Microscopy -Belianinov Nanofiber Characterization by Raman Scanning Microscopy -Khmaladze Quantification of Nanostructure Orientation via Image Processing -Abukhdeir Chemometrics and Super-Resolution at the Service of Nanoscience: Aerosols Characterization in Hyperspectral Raman Imaging - Offroy Atomic Force Microscope Nanoscale Mechanical Mapping -Liu Electron Holography for Mapping Electric Fields and Charge - Martha R. McCartney and David J. Smith Terahertz Spectroscopy for Nanomaterial Characterization -Xu TXRF Spectrometry in Conditions of Planar X-Ray Waveguide-Resonator Application -Egorov Nanoscale XPEEM Spectromicroscopy - Vaz Integrating Cavities and Ring-Down Spectroscopy -Fry Inductively Coupled Plasma Mass Spectrometry for Nanomaterial Analysis -Laborda Determination of Nanomaterial Electronic Structure via Variable-Temperature Variable-Field Magnetic Circular Photoluminescence (VTVH-MCPL) Spectroscopy -Knappenberger Photoluminescence Spectroscopy of Single Semiconductor Quantum Dots - Kusova Scanning Electrochemical Microscopy and its Potential in Nanomaterial Characterization - Kranz Nanostructured Materials Obtained by Electrochemical Methods: From Fabrication to Application in Sensing, Energy Conversion and Storage - Inguanta New Trends in Nanoscale Electrodes and Electrochemistry: The Role of Dimensionality - Bandaru.
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• Nanophotonic Devices Based on Low-Voltage Emission of 2D Electron Gas - Kim
• Polarized Nano-Optics - Brasselet
• Optical Properties of Semiconductor Nanostructures - Cantarero
• Hybrid Phase-Change Nanophotonic Circuits - Pernice
• X-Ray Nanophotonics Based on Planar X-Ray Waveguide Resonator - Egorov
• Optical Tweezers - Li
• Metal Nanostructures with Plasmonically Enhanced Raman and Photoluminescence Signals - Nam
• GaN Nanoflowers: Growth to Optoelectronic Device - Gupta
• The Future of Nanoelectronics - Deleonibus
• Semimetal Nanoelectronics: Quantum Confinement and Surface Chemistry as Design Tools - Greer
• Neuromorphic Nanoelectronics - Fairfield
• Single-Electronics: Modeling and Simulation Techniques - Santos Pes
• Single Electron Transport and Possible Quantum Computing in 2D Materials - Chiu
• Assembly of Plasmonic Nanoparticles - Zheng
• Coulomb Blockade Plasmonic Switch - Gordon
• Amplification of Surface Plasmons - Wartak
• Magneto-Plasmonics in Purely Ferromagnetic Subwavelength Arrays - Papaioannou
• Cathodoluminescence of Nanoplasmonics - Yamamoto
• Biosensing under Surface Plasmon Resonance Conditions - Snopok
• Plasmonic Optical Antenna and its Enhancement to Infrared Photodetectors - Lu.
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21st Century Nanoscience - A Handbook: Nanophotonics, Nanoelectronics, and Nanoplasmonics (Volume 6) will be the most comprehensive, up-to-date large reference work for the field of nanoscience. Handbook of Nanophysics by the same editor published in the fall of 2010 and was embraced as the first comprehensive reference to consider both fundamental and applied aspects of nanophysics. This follow-up project has been conceived as a necessary expansion and full update that considers the significant advances made in the field since 2010. It goes well beyond the physics as warranted by recent developments in the field. This sixth volume in a ten-volume set covers nanophotonics, nanoelectronics, and nanoplasmonics. Key Features: Provides the most comprehensive, up-to-date large reference work for the field. Chapters written by international experts in the field. Emphasises presentation and real results and applications. This handbook distinguishes itself from other works by its breadth of coverage, readability and timely topics. The intended readership is very broad, from students and instructors to engineers, physicists, chemists, biologists, biomedical researchers, industry professionals, governmental scientists, and others whose work is impacted by nanotechnology. It will be an indispensable resource in academic, government, and industry libraries worldwide. The fields impacted by nanophysics extend from materials science and engineering to biotechnology, biomedical engineering, medicine, electrical engineering, pharmaceutical science, computer technology, aerospace engineering, mechanical engineering, food science, and beyond.
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This up-to-date reference is the most comprehensive summary of the field of nanoscience and its applications. It begins with fundamental properties at the nanoscale and then goes well beyond into the practical aspects of the design, synthesis, and use of nanomaterials in various industries. It emphasizes the vast strides made in the field over the past decade - the chapters focus on new, promising directions as well as emerging theoretical and experimental methods. The contents incorporate experimental data and graphs where appropriate, as well as supporting tables and figures with a tutorial approach. .
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• Symbols, Units, and Nomenclature.- Mathematical Basics.- Acoustics.- Astronomy.- Astrophysics and Cosmology.- Atomic and Molecular Collision Processes.- Atomic Spectroscopy.- Biological Physics.- Crystallography.- Earth, Ocean and Atmosphere Physics.- Electricity and Magnetism.- Elementary Particles.- Fluid Dynamics.- Geophysics and Geodesy.- Mechanics.- Medical Physics.- Molecular Spectroscopy and Structure.- Nonlinear Physics and Complexity.- Nuclear Physics.- Optics.- Particle Accelerators and Storage Rings.- Plasma Physics.- Polymer Physics.- Quantum Theory.- Solid State Physics.- Surfaces and Films.- Thermodynamics and Thermophysics.- Practical Lab Data.
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This is a major revision of a classic, best selling reference book. Originally published by the American Institute of Physics under the title "Physics Vade Mecum" in 1981, and then the second edition in 1989 with the new title "A Physicist's Desk Reference", this third edition has been completely updated and modernized to reflect current modern physics. The book is a concise compilation of the most frequently used physics data and formulae with their derivations. This revision has six more chapters than the second edition, outdated chapters dropped, and new chapters added on atmospheric physics, electricity and magnetism, elementary particle physics, fluid dynamics, geophysics, nonlinear physics, particle accelerators, polymer physics, and quantum theory.There is a new last chapter on practical laboratory data. The references and bibliographies have been updated. This book is an indispensable tool for the researcher, professional and student in physics as well as other scientists who use physics data. The editors of this volume are Richard Cohen, author of the first two chapters of PDR and the "Physics Quick Reference Guide"; David Lide, one of the editors of the previous two editions and the editor of the "CRC Handbook of Physics and Chemistry"; and George Trigg, editor of the "Encyclopedia of Physics" and the "Encyclopedia of Applied Physics" (VCH). The market for this classic reference book includes the practicing scientist, including engineers, chemists, and biologists; and students.
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• The Practical Basics of Spectrometry: J. Workman, Optical Spectrometers. J. Workman, UV-VIS-NIR Spectrometry. J. Coates, IR Spectrometry: Sample Preparation and Spectrum Acquisition. J. Duckworth, Spectroscopic Quantitative Analysis. J. Duckworth, Spectroscopic Qualitative Analysis. Reflectance Measurements of Solids: A. Springsteen, Reflectance Spectroscopy: An Overview of Classification and Techniques. J. Workman, Spectroscopy of Solids. A. Springsteen, Standards for Reflectance Measurements. K.A. Snail and L.M. Hanssen, Accurate Measurements of Spectral Reflectance: Directional Hemispherical and Hemispherical Directional Reflectance Measurements Using Conic Mirror Reflectometers. S. McCall, The Bi-directional Reflectance Distribution Function. Practical Application of Spectroscopic Measurement: E.W. Ciurczak, Selecting a Spectroscopic Method by Industrial Application. J. Murray Stewart, Color and Solar Transmittance Measurements. S. White, Optical Spectroscopy of New Materials. J.F. Cordaro, Spectroscopy of Ceramics. E. Ciurczak, Spectroscopy Using Flowing Systems for Chemical, Pharmaceutical, and Biomedical Applications. S. Ghosh, Textile Application of Molecular Spectroscopy. J.M. Stewart, Solar Measurements. Glossary. Appendix.
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This book delineates practical, tested, general methods for ultraviolet, visible, and infrared spectrometry in clear language for novice users, and serves as a reference resource for advanced spectroscopists. "Applied Spectroscopy" includes important information and equations which will be referred to regularly. The book emphasizes reflectance and color measurements due to their common usage in todays spectroscopic laboratories, and contains methods for selecting measurement technique as well as solar and color measurements. It is written by experts in the field, this text covers spectrometry of new materials, ceramics, and textiles, and provides an appendix of practical reference data for spectrometry. This book includes topics such as: Practical aspects of spectrometers and spectrometry; Sample preparation; Chemometrics and calibration practices; Reflectance measurements; and Standard materials measurements. An emphasis is placed on reflectance and color measurements due to their common usage in today's spectroscopic laboratories. Methods for selecting a measurement technique are included as well as solar measurements and reference information on sources, detectors, optical fiber and window materials. Additionally, spectrometry of new materials, ceramics, and textiles are covered by respective experts in their fields. An appendix of practical reference data for spectrometry and an extensive index are also included. Practitioners, researchers, and students will find this book useful in their daily working activity, in teaching, and in studies.
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• Part I: Spectroscopy.
• 1: Spectroscopy of molecular beams: an overview.
• 2: Magnetic and electric resonance spectroscopy.
• 3: Beam-maser spectroscopy.
• 4: Quantum amplifiers and oscillators.
• 5: Metrology with molecular beams.
• 6: Infrared laser spectroscopy.
• 7: Visible and UV spectroscopy: physical aspects.
• 8: Photofragment spectroscopy.
• 9: Fourier-transform microwave spectroscopy.
• 10: Fourier-transform methods: infrared. Part II: Surface Scattering.
• 11: General principles and methods.
• 12: Elastic scattering of atoms.
• 13: Rotational inelastic scattering.
• 14: Single phonon inelastic helium scattering.
• 15: Multiple phonon inelastic scattering.
• 16: Scattering from disordered surfaces.
• 17: Reactive scattering.
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• Part 1 Basic techniques: introduction, G.Scoles
• free jet sources, D.R.Miller
• low energy pulsed beam sources, W.R.Gentry
• other low energy beam sources, H.Pauly
• high energy beam sources, H.Pauly
• detection principles, D.Bassi
• ionization detectors - ion production and mass selection and ion detection, D.Bassi
• spectroscopic detection methods, U.Hefter and K.Bergmann
• accommodation, accumulation and other detection methods, M.Zen
• state selection by non-optical methods, J.Reuss
• state selection via optical methods, K. Bergmann
• velocity selection by mechanical methods, C.J.N.van den Meijdenberg
• velocity measurements via time of flight measurements, D.J.Auerbach
• molecular beams of clusters, S.Leutwyler and M.Kappes
• molecular beam epitaxy, K.Ploog
• molecular beams in high energy physics, U. Valbusa. Part 2 Molecular scattering: general principles and methods, U.Buck
• elastic scattering - integral cross sections, J.Biesen
• differential cross sections, U.Buck
• inelastic scattering - energy loss methods, U.Buck
• inelastic scattering - optical methods, P.J. Dagdigian
• reactive scattering - non-optical methods, Y.T.Lee
• - optical methods, P.J.Dagdigian, scattering experiments which state selectors, S.Stolte
• scattering experiments with laser excited beams, R.Duren
• experiments with spin polarized beams, S.Iannotta.
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This is the second volume of an advanced handbook on experimental molecular beam methods, in which seventeen specialists cover the areas of molecular beam spectroscopy and surface scattering. It is designed to be used both as a reference book in the laboratory and as a supplementary text for graduate courses in spectroscopy and gas-surface interactions. The text is split into two parts dealing with these two topics. The spectroscopy part introduces the special features connected with using beams in spectroscopy and then goes on to discuss the subject, going through the spectrum from low to high frequencies. The surface scattering part introduces general instrumentation problems, followed by a series of chapters in which elastic, rotationally inelastic, single-phonon, multi-phonon and chemical scattering are discussed. Scattering from non-ordered surfaces is covered separately. The emphasis throughout is on experimental methods, which includes discussions on data analysis and calibrations. Numerous examples of data are shown and to allow for the understanding of these the theory underlying the most common measurements is also presented.
(source: Nielsen Book Data)
This comprehensive handbook describes new experimental approaches for the growing number of chemists, physicists, and engineers working with atomic and molecular beams. With an emphasis on aspects of design, construction and proper data analysis, contributors explore many topics of microscopic chemical physics such as elastic, inelastic, and reactive molecular collisions, clusters, and free-standing jets. Also included are descriptions of experimental set-ups and examples of data obtained in molecular beam experiments, with clear explanations of their significance and importance. The book is a practical guide that will help in planning the structure of experiments and analysing their results.
(source: Nielsen Book Data)