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Experimental solid state physics --- Theoretical spectroscopy. Spectroscopic techniques --- fysicochemie --- Electron energy loss spectroscopy --- Electron microscopy --- Microscopy --- EELS (Spectrum analysis) --- Energy loss spectroscopy, Electron --- Spectroscopy, Electron energy loss --- Electron spectroscopy --- Electron microscopy. --- Electron energy-loss spectroscopy

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Within the last 30 years, electron energy-loss spectroscopy (EELS) has become a standard analytical technique used in the transmission electron microscope to extract chemical and structural information down to the atomic level.  In two previous editions, Electron Energy-Loss Spectroscopy in the Electron Microscope has become the standard reference guide to the instrumentation, physics and procedures involved, and the kind of results obtainable. Within the last few years, the commercial availability of lens-aberration correctors and electron-beam monochromators has further increased the spatial and energy resolution of EELS. This thoroughly updated and revised Third Edition incorporates these new developments, as well as advances in electron-scattering theory, spectral and image processing, and recent applications in fields such as nanotechnology. The appendices now contain a listing of inelastic mean free paths and a description of more than 20 MATLAB programs for calculating EELS data. Considered the "Bible of EELS" Presents the only in-depth, single-author text for the still-expanding field of TEM-EELS Responds to many requests for the first new edition of this classic work since 1996 Includes discussion of new spectrometer and detector designs, together with spectral-analysis techniques such as Bayesian deconvolution and multivariate statistical analysis Provides extended discussion of anisotropic materials, retardation effects, delocalization of inelastic scattering, and the simulation of energy-loss fine structure. Describes recent applications of EELS to fields such as nanotechnology, electronic devices and carbon-based materials. Offers extended coverage of radiation damage and delocalization as limits to spatial resolution. From reviews of the first and second edition: "The text....contains a wealth of practical detail and experimental insight....This book is an essential purchase for any microscopist who is using, or planning to use, electron spectroscopy or spectroscopic imaging." – JMSA "Provides the advanced student with an indispensable text and the experienced researcher with a valuable reference." -- American Scientist.

Electron microscopy. --- Electrons. --- Energy. --- Spectroscopy. --- Electron energy loss spectroscopy --- Electron microscopy --- Chemical & Materials Engineering --- Physics --- Engineering & Applied Sciences --- Physical Sciences & Mathematics --- Materials Science --- Light & Optics --- Electron energy loss spectroscopy. --- EELS (Spectrum analysis) --- Energy loss spectroscopy, Electron --- Spectroscopy, Electron energy loss --- Materials science. --- Solid state physics. --- Microscopy. --- Nanotechnology. --- Materials Science. --- Characterization and Evaluation of Materials. --- Spectroscopy/Spectrometry. --- Spectroscopy and Microscopy. --- Solid State Physics. --- Molecular technology --- Nanoscale technology --- High technology --- Analysis, Microscopic --- Light microscopy --- Micrographic analysis --- Microscope and microscopy --- Microscopic analysis --- Optical microscopy --- Optics --- Solids --- Analysis, Spectrum --- Spectra --- Spectrochemical analysis --- Spectrochemistry --- Spectroscopy --- Chemistry, Analytic --- Interferometry --- Radiation --- Wave-motion, Theory of --- Absorption spectra --- Light --- Spectroscope --- Material science --- Physical sciences --- Qualitative --- Microscopy --- Electron spectroscopy --- Surfaces (Physics). --- Surface chemistry --- Surfaces (Technology) --- Spectrometry --- Analytical chemistry

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Ion bombardment --- Particle range (Nuclear physics) --- Solids --- Stopping power (Nuclear physics) --- Atomic stopping power --- Average ionization potential --- Kinetic energy of particles (Nuclear physics) --- Stopping cross section --- Collisions (Nuclear physics) --- Ionization --- Matter --- Nuclear reactions --- Particles (Nuclear physics) --- Radioactivity --- Linear energy transfer --- Solid state physics --- Transparent solids --- Energy loss of nuclear particles --- Range of particles (Nuclear physics) --- Particle tracks (Nuclear physics) --- Straggling (Nuclear physics) --- Beams, Ion --- Bombardment, Ion --- Impact, Ion --- Ion beams --- Ion impact --- Ionic bombardment --- Ions --- Properties --- Measurement

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620.9 --- 63 --- 504.062 --- Economics of energy in general --- Agriculture and related sciences and techniques. Forestry. Farming. Wildlife exploitation --- Protection, rational use, restoration of natural resources. Sustainable development --- 504.062 Protection, rational use, restoration of natural resources. Sustainable development --- 63 Agriculture and related sciences and techniques. Forestry. Farming. Wildlife exploitation --- 620.9 Economics of energy in general --- Plant production(Energy Use) --- Drying in agriculture(Energy Economization) --- Greenhouse energy loss reduction --- Animal production(Energy Use) --- Food industry(Energy Economization) --- Agricultural machinery(Energy Economization) --- Energy conservation in agriculture

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This monograph focusses on the influence of a strong magnetic field on the interactions between charged particles in a many-body system. Two complementary approaches, the binary collision model and the dielectric theory are investigated in both analytical and numerical frameworks. In the binary collision model, the Coulomb interaction between the test and the target particles is screened because of the polarization of the target. In the continuum dielectric theory one considers the interactions between the test particle and its polarization cloud. In the presence of a strong magnetic field, there exists no suitable parameter of smallness. Linearized and perturbative treatments are not more valid and must be replaced by numerical grid or particle methods. Applications include the electron cooling of ion beams in storage rings and the final deceleration of antiprotons and heavy ion beams in traps.

Stopping power (Nuclear physics) --- Energy dissipation. --- Plasma (Ionized gases) --- Particle range (Nuclear physics) --- Magnetic fields. --- Mathematical models. --- Fields, Magnetic --- Field theory (Physics) --- Geomagnetism --- Magnetics --- Energy loss of nuclear particles --- Range of particles (Nuclear physics) --- Ion bombardment --- Particle tracks (Nuclear physics) --- Particles (Nuclear physics) --- Straggling (Nuclear physics) --- Gaseous discharge --- Gaseous plasma --- Magnetoplasma --- Ionized gases --- Degradation, Energy --- Dissipation (Physics) --- Energy degradation --- Energy losses --- Losses, Energy --- Force and energy --- Atomic stopping power --- Average ionization potential --- Kinetic energy of particles (Nuclear physics) --- Stopping cross section --- Collisions (Nuclear physics) --- Ionization --- Matter --- Nuclear reactions --- Radioactivity --- Linear energy transfer --- Properties --- Measurement --- Classical Electrodynamics. --- Atomic, Molecular, Optical and Plasma Physics. --- Atoms and Molecules in Strong Fields, Laser Matter Interaction. --- Plasma Physics. --- Optics. --- Electrodynamics. --- Atoms. --- Physics. --- Plasma (Ionized gases). --- Natural philosophy --- Philosophy, Natural --- Physical sciences --- Dynamics --- Chemistry, Physical and theoretical --- Stereochemistry --- Physics --- Light --- Constitution