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Charged particle imaging has revolutionized experimental studies of photodissociation and bimolecular collisions. Written in a tutorial style by some of the key practitioners in the field, this book gives a comprehensive account of the technique and describes many of its applications. The book is split into two parts. Part I is intended as a series of tutorials. It explains the basic principles of the experiment and the numerical methods involved in interpreting experimental data. Part II describes a number of different applications. These chapters are more directly research oriented, the aim being to introduce the reader to the possibilities for future experiments. This comprehensive book will be of primary interest to researchers and graduate students working in chemical and molecular physics who require an overview of the subject as well as ideas for future experiments.

Imaging systems in chemistry. --- Molecular dynamics. --- Molecular orbitals. --- Molecules. --- Molecular dynamics --- Imaging systems in chemistry --- Physical & Theoretical Chemistry --- Chemistry --- Physical Sciences & Mathematics --- Chemical imaging systems --- Chemical apparatus --- Dynamics, Molecular --- Dynamics

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Visualizing chemical components in a specimen is an essential technology in many branches of science and practical applications. This book deals with electrochemical imaging techniques based on semiconductor devices with capability of spatially resolved sensing. Two types of such sensing devices have been extensively studied and applied in various fields, i.e., arrayed sensors and light-addressed sensors. An ion-sensitive field-effect transistor (ISFET) array and a charge-coupled device (CCD) ion image sensor are examples of arrayed sensors. They take advantage of semiconductor microfabrication technology to integrate a large number of sensing elements on a single chip, each representing a pixel to form a chemical image. A light-addressable potentiometric sensor (LAPS), on the other hand, has no pixel structure. A chemical image is obtained by raster-scanning the sensor plate with a light beam, which can flexibly define the position and size of a pixel. This light-addressing approach is further applied in other LAPS-inspired methods. Scanning photo-induced impedance microscopy (SPIM) realized impedance mapping and light-addressable electrodes/light-activated electrochemistry (LAE) realized local activation of Faradaic processes. This book includes eight articles on state-of-the-art technologies of light-addressing/chemical imaging devices and their application to biology and materials science.

Research & information: general --- CCD ion sensor --- multi-ion image --- CMOS technology --- ink-jet printing --- bioactive cations --- LAPS --- chemical imaging --- spatial and temporal resolution --- semiconductor --- microfluidics --- photoelectrochemistry --- InGaN/GaN epilayer --- cell imaging --- light-activated electrochemistry --- light-addressable potentiometric sensor --- chemical imaging sensor --- field-effect sensor --- light-addressable potentiometric sensor (LAPS) --- Lactobacillus brevis --- Escherichia coli --- Corynebacterium glutamicum --- cellular metabolism --- differential cell-based measurement --- multi-analyte analysis --- extracellular acidification --- DNA biosensor --- ZnO nanorod arrays --- label-free detection --- E. coli --- light-addressable electrode --- light-addressable cell stimulation and photoelectrochemistry --- photoelectrochemical deposition --- crevice corrosion --- potential distribution --- crevice gap

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Electronic books. -- local. --- Imaging systems in chemistry. --- Molecular dynamics. --- Spectrum analysis. --- Imaging systems in chemistry --- Molecular dynamics --- Spectrum analysis --- Physical & Theoretical Chemistry --- Chemistry --- Physical Sciences & Mathematics --- Analysis, Spectrum --- Spectra --- Spectrochemical analysis --- Spectrochemistry --- Spectroscopy --- Dynamics, Molecular --- Chemical imaging systems --- Chemistry, Analytic --- Interferometry --- Optics --- Radiation --- Wave-motion, Theory of --- Absorption spectra --- Light --- Spectroscope --- Dynamics --- Chemical apparatus --- Qualitative --- Spectrometry --- Analytical chemistry

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This volume demonstrates the novel possibilities in sensing and imaging offered by the assembly of organic dyes into nanoparticles and nanocomposites and by the application of strongly fluorescent noble metal clusters and conjugated polymers. Its 14 chapters, written by top experts in this field, provide in-depth information on the coupling of organic dyes to different molecular and supramolecular structures, on their incorporation into polymeric nanoparticles and on the nanostructures that can be formed by some of the dyes. Bright and photostable several-atom clusters of gold and silver are e

Conjugated polymers. --- Fluorescence spectroscopy. --- Imaging systems in biology. --- Imaging systems in chemistry. --- Coloring Agents --- Luminescent Agents --- Macromolecular Substances --- Biomedical and Dental Materials --- Spectrum Analysis --- Fluorometry --- Nanostructures --- Laboratory Chemicals --- Spectrometry, Fluorescence --- Fluorescent Dyes --- Indicators and Reagents --- Polymers --- Nanoparticles --- Specialty Uses of Chemicals --- Chemicals and Drugs --- Chemistry Techniques, Analytical --- Luminescent Measurements --- Manufactured Materials --- Chemical Actions and Uses --- Photometry --- Investigative Techniques --- Technology, Industry, and Agriculture --- Analytical, Diagnostic and Therapeutic Techniques and Equipment --- Technology, Industry, Agriculture --- Chemistry --- Analytical Chemistry --- Physical Sciences & Mathematics --- Chemical imaging systems --- Biological imaging systems --- Fluorescence spectrometry --- Spectroscopy, Fluorescence --- Chemistry. --- Molecular biology. --- Analytical chemistry. --- Medical biochemistry. --- Biology --- Biophysics. --- Biological physics. --- Optical materials. --- Electronic materials. --- Analytical Chemistry. --- Molecular Medicine. --- Biophysics and Biological Physics. --- Medical Biochemistry. --- Optical and Electronic Materials. --- Biological Techniques. --- Technique. --- Chemical apparatus --- Organic semiconductors --- Conducting polymers --- Luminescence spectroscopy --- Fluorescent probes --- Analytical biochemistry. --- Medicine. --- Biochemistry. --- Cytology --- Biological and Medical Physics, Biophysics. --- Research --- Methodology. --- Optics --- Materials --- Biological chemistry --- Chemical composition of organisms --- Organisms --- Physiological chemistry --- Medical sciences --- Clinical sciences --- Medical profession --- Human biology --- Life sciences --- Pathology --- Physicians --- Analytic biochemistry --- Biochemistry --- Chemistry, Analytic --- Cell biology --- Cellular biology --- Cells --- Cytologists --- Composition --- Health Workforce --- Bioanalytic chemistry --- Bioanalytical chemistry --- Analytical chemistry --- Biology—Technique. --- Electronic materials --- Medical biochemistry --- Pathobiochemistry --- Pathological biochemistry --- Biological physics --- Physics --- Molecular biochemistry --- Molecular biophysics --- Biophysics --- Biomolecules --- Systems biology --- Analysis, Chemical --- Analytic chemistry --- Chemical analysis

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Molecular probes --- Magnetic resonance imaging --- Molecular Imaging --- Magnetic Resonance Imaging --- Magnetic resonance imaging. --- Molecular probes. --- Bioprobes --- Probes, Molecular --- Clinical magnetic resonance imaging --- Diagnostic magnetic resonance imaging --- Functional magnetic resonance imaging --- Imaging, Magnetic resonance --- Medical magnetic resonance imaging --- MR imaging --- MRI (Magnetic resonance imaging) --- NMR imaging --- Nuclear magnetic resonance --- Nuclear magnetic resonance imaging --- Functional Magnetic Resonance Imaging --- Imaging, Chemical Shift --- Proton Spin Tomography --- Spin Echo Imaging --- Steady-State Free Precession MRI --- Tomography, MR --- Zeugmatography --- Chemical Shift Imaging --- MR Tomography --- MRI Scans --- MRI, Functional --- Magnetic Resonance Imaging, Functional --- Magnetization Transfer Contrast Imaging --- NMR Imaging --- NMR Tomography --- Tomography, NMR --- Tomography, Proton Spin --- fMRI --- Chemical Shift Imagings --- Echo Imaging, Spin --- Echo Imagings, Spin --- Functional MRI --- Functional MRIs --- Imaging, Magnetic Resonance --- Imaging, NMR --- Imaging, Spin Echo --- Imagings, Chemical Shift --- Imagings, Spin Echo --- MRI Scan --- MRIs, Functional --- Scan, MRI --- Scans, MRI --- Shift Imaging, Chemical --- Shift Imagings, Chemical --- Spin Echo Imagings --- Steady State Free Precession MRI --- Imaging, Molecular --- Diagnostic use --- structural analysis --- spectroscopy --- crystallography --- dynamic imaging --- Molecular biology --- Affinity labeling --- Cross-sectional imaging --- Diagnostic imaging --- Magnetic Resonance Spectroscopy --- Anatomy, Cross-Sectional --- Technique --- Imaging systems in chemistry --- Molecular Imaging. --- Magnetic Resonance Imaging. --- Chemical imaging systems --- Chemical apparatus --- Imaging systems in chemistry. --- Animal Biochemistry --- Magnetic Resonance Image --- Image, Magnetic Resonance --- Magnetic Resonance Images --- Resonance Image, Magnetic --- Science --- Crystal chemistry