「Spectroscopy」の共起表現一覧(1語右で並び替え)

Spectroscopy

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  • At the end of the war, he worked on Raman spectroscopy, a field in which he was regarded as one of
  • ped pure absorption phase multi-dimensional spectroscopy, a technique now widely used in protein str
  • 0 nmi) orbit for 'experiments in stellar UV spectroscopy', a 556-1,296 km (300-700 nmi) orbit for 'e
  • fundamental difference in how IR and Raman spectroscopy access the vibrational transitions.
  • lso developed the areas of multiple-quantum spectroscopy, adiabatic sech/tanh inversion pulses, zero
  • Fluorescence spectroscopy aka fluorometry or spectrofluorometry, is a
  • Saturated spectroscopy allows the doppler broadened peak to be res
  • frequencies of light emitted in fluorescent spectroscopy, along with their relative intensities, the
  • l telescopes are usually not well-suited to spectroscopy, although some useful spectroscopic work ca
  • n can often be detected and measured by NMR spectroscopy, among other methods.
  • ouis and Kumar used energy dispersive X-ray spectroscopy analysis of the red solid and showed that t
  • 1990 by the German Working Group of Applied Spectroscopy, and is endowed with €2500 by PerkinElmer,
  • are used in different applications such as spectroscopy and sensing, laser power delivery and fiber
  • mplexes, mechanisms of inorganic reactions, spectroscopy and magneto-chemistry of inorganic compound
  • t Propulsion Laboratory, who specializes in spectroscopy and photometry of minor planets.
  • efore, of use in nuclear magnetic resonance spectroscopy; and spectrometers specially adapted to det
  • tum and multi-particle transitions in radio spectroscopy and quantum radiophysics," was published in
  • erhard published numerous investigations on spectroscopy and on photographic photogrametry.
  • This was the first use of X-ray spectroscopy and also one more step towards the creation
  • Some techniques, such as Raman spectroscopy and Energy Dispersive X-Ray Diffraction (ED
  • ch Miller is mainly remembered today are in spectroscopy and astrochemistry, new fields in his time.
  • mpounds including that for infrared and NMR spectroscopy and mass spectrometry.
  • erahertz radiation in time-domain terahertz spectroscopy and terahertz imaging.
  • The national centre for electron spectroscopy and surface analysis (NCESS), which has a h
  • scattering spectrometer for high resolution spectroscopy, and magnetism and liquid reflectometers fo
  • alline structure was determined by both NMR spectroscopy and X-ray crystallography in 1963.
  • is the director of Institute for Ultrafast Spectroscopy and Lasers.
  • bration in the application of near infrared spectroscopy and development of predictive models for us
  • hemical shift in nuclear magnetic resonance spectroscopy and represents difference of the frequency
  • Spectral imaging is a branch of spectroscopy and of photography in which a complete spec
  • d for CCD direct imaging, medium-dispersion spectroscopy and visual observing.
  • cientific and technical use is called gamma spectroscopy, and gamma-ray spectrometers are the instru
  • ly obtained by X-ray crystallography or NMR spectroscopy and submitted by biologists and biochemists
  • of molecules through paramagnetic resonance spectroscopy and for the introduction and biological app
  • ly 3, 2008 by Sato et al., who used Doppler Spectroscopy and found the wobbling of the star caused b
  • igated the structure of the Milky Way, star spectroscopy and gas nebula, and searched intensively fo
  • ion is frequently used in atomic absorption spectroscopy and gas chromatography.
  • He specialized in solar spectroscopy and mapped the distribution of magnetic fie
  • wavelength spectrograph, FOBOS, for general spectroscopy and precision radial velocity measurement.
  • value throughout nuclear magnetic resonance spectroscopy and is particularly valuable for determinin
  • py, cyclic spectrovoltammetry, photocurrent spectroscopy, and electrochemical quartz crystal microba
  • He combined NMR spectroscopy and modeling to demonstrate for the first t
  • y, flow cytometry, fluorescence correlation spectroscopy and ELISA.
  • In Fourier Transform NMR spectroscopy and imaging, a pulse sequence describes a s
  • phenomenon is referred to as inverse Raman spectroscopy, and a record of the continuum is referred
  • as published papers on astrophysical plasma spectroscopy and structure and energy balance in cool st
  • oder systems, dental CAD/CAM systems, Raman spectroscopy and medical devices for functional neurosur
  • ze in Physics in 1917 for his work in X-ray spectroscopy and related areas in the study of X-rays (R
  • lexes, the Department of Photochemistry and Spectroscopy and the Department of Quantum Theory of Sol
  • adio astronomy, Pulsar physics, Space radio spectroscopy, and Pulsar astrometry.
  • His thesis research was on atomic spectroscopy and the Stark effect, an area successfully
  • a rays and beta particles, please see gamma spectroscopy and liquid scintillation counting respectiv
  • etic resonance imaging, spatially selective spectroscopy and studies of diffusion via NMR.
  • arded for his work on laser-based precision spectroscopy, and the optical frequency comb technique.
  • ent of modern instruments: visible imagery, spectroscopy and polarimetry are routinely conducted.
  • izing surface plasmon resonance, dielectric spectroscopy and molecular neurobiology to successfully
  • s to the integration of physical chemistry, spectroscopy and organic chemistry for the understanding
  • He worked in astronomical photometry and spectroscopy and is well known for creating instruments
  • Currently NIR spectroscopy applications dominate the PAT projects.
  • Timashev developed a flicker-noise spectroscopy approach for extracting information from th
  • Coherent or resonance spectroscopy are techniques where the radiative energy c
  • nic generation and sum frequency generation spectroscopy are best known and also widely used by scie
  • other techniques such as circular dichroism spectroscopy are often used as faster alternatives.
  • in a centrosymmetric molecule, IR and Raman spectroscopy are mutually exclusive.
  • hniques, like X-ray crystallography and NMR spectroscopy, are widely used in chemistry and biochemis
  • Gas chromatography and mid-infrared spectroscopy are other methods in use.
  • NMR and IR spectroscopy) are far superior in determining the identi
  • by an ac pulse, and monitored by reflection spectroscopy as well as light scattering.
  • urplish coordination complex is used in NMR spectroscopy as a relaxation agent because of its solubi
  • ted DCM is not a common solvent used in NMR spectroscopy as it is reasonably expensive.
  • in conjunction with electron spin resonance spectroscopy, as a reagent in organic synthesis, and as
  • Aromatic ring currents are relevant to NMR spectroscopy, as they dramatically influence the chemica
  • y X-ray diffraction and X-ray photoelectron spectroscopy as the mixed-valence phase PuIV3−xPuVIxO6+x
  • The silylene can be observed with UV spectroscopy at 520 nm and is short-lived with a chemica
  • D as a brown dwarf was confirmed by Doppler spectroscopy at the Cerro Tololo Interamerican Observato
  • This compound was detected by infrared spectroscopy at 30 K but has not been isolated as a stab
  • c from Oxford and was appointed lecturer in spectroscopy at King's College London.
  • an be differentiated from NAA in vivo by MR spectroscopy at 3 Tesla.
  • German physicist who made contributions to spectroscopy, atomic physics, the structure of matter, a
  • Spectroscopy, based on the interaction of the analyte wi
  • CT) monochromator) or FT (Fourier transform spectroscopy based), and CCD detectors.
  • In general Electron Energy Loss Spectroscopy bases on the energy losses of electrons whe
  • used as thermal light sources for infrared spectroscopy because their spectral behaviour correspond
  • He was an expert in spectroscopy, being one of the first to determine that t
  • ation include X-ray crystallography and NMR spectroscopy, both of which can produce information at a
  • It was occasionally used in the field of spectroscopy, but its use has been superseded by teraher
  • advanced physics courses, including one in spectroscopy by Janet T. Howell.
  • Infrared (IR) spectroscopy by ATR is applicable to the same chemical o
  • Any form of spectroscopy can be used in this way so long as the anal
  • Spectroscopy can be used to measure the absorption of li
  • n, she discovered that electron energy loss spectroscopy can be used to detect species absorbed in t
  • Gamma spectroscopy can narrow down the potential nuclear explo
  • Fourier transform infrared (FTIR) spectroscopy can be used to experimentally study rotatio
  • NMR spectroscopy can also be used to check the level of impu
  • MIR spectroscopy can distinguish subtle changes in chemistry
  • Dark-current spectroscopy can be used to determine the defects presen
  • It is ranked number 7 out of 39 in the Spectroscopy category.
  • His fields of research included spectroscopy, charge transfer complexes, solution theory
  • nce, double resonance, selective excitation spectroscopy, coherent processes in excited states, e.g.
  • Polarization spectroscopy comprises a set of spectroscopic techniques
  • was done using low-intermediate-resolution spectroscopy confirmed the presence of a substellar obje
  • The term is commonly used in absorption spectroscopy, corresponding to a wavelength of maximum a
  • nted areas, such as liquid fuel technology, spectroscopy, crystallography, system engineering, biote
  • Other spectroscopy databanks can be used.
  • th purity sufficient to enable their use as spectroscopy detectors.
  • Electric field NMR (EFNMR) spectroscopy differs from conventional NMR in that a sam
  • partment of Astronomy, UCL, attached to the Spectroscopy Division of UKAEA Culham Laboratory, 1966-6
  • of analytical instrumentation for emission spectroscopy, dual-beam, recording infra-red absorption
  • ed THF is a rarely used as a solvent in NMR spectroscopy due to its expense.
  • orn British physicist known for his work in spectroscopy, electrochemistry, optics, X-radiography an
  • as mapping by energy dispersive X-ray (EDX) spectroscopy, electron energy loss spectroscopy (EELS) a
  • ues such as surface plasmon resonance (SPR) spectroscopy, ellipsometry, or dual polarisation interfe
  • ke biophotonics, laser-excited luminescence spectroscopy, etc.
  • Topics includes: general solid state spectroscopy, experimental and theoretical analysis of c
  • in protein Electron paramagnetic resonance spectroscopy experiments.
  • However, subsequent studies using Doppler spectroscopy failed to detect the radial velocity variat
  • These include mid-IR spectroscopy, fiber-optic sensors, thermometry, and imag
  • etry (MS), nuclear magnetic resonance (NMR) spectroscopy, fluorescence spectroscopy, dual polarisati
  • cy modes have been indeed observed by Raman spectroscopy for a number of protein molecules and diffe
  • tenuated total reflection Fourier transform spectroscopy for on-chip monitoring of solute concentrat
  • the Second World War he worked on infra-red spectroscopy for the Ministry of Aircraft Production, an
  • a modified form of electron spin resonance spectroscopy for the analysis of chemical transformation
  • spearheaded the technique of multi-aperture spectroscopy for observing very faint, high redshift gal
  • NBS, have remained essential references in spectroscopy for decades.
  • biomedical optics including tissue optical spectroscopy, frequency-domain photon migration, non-lin
  • Butler, and Marcy et al. using the Doppler spectroscopy from the Anglo-Australian Telescope.
  • It uses spectroscopy from the regularly updated GEISA spectral l
  • A with mass spectrometry, Fourier transform spectroscopy, gas chromatography, or Optical In-Situ Evo
  • sed techniques such as Resonance Ionization Spectroscopy has allowed relatively easy access to these
  • 2+, which has been observed using microwave spectroscopy, has a calculated binding energy of 6 kcal/
  • mic light scattering and photon correlation spectroscopy has made possible the measurement of the ti
  • g (CP/MAS) nuclear magnetic resonance (NMR) spectroscopy have been used to characterize nanocellulos
  • Advances in Laser Spectroscopy I, ed. A. H. Zewail, SPIE, Bellingham, 1977
  • Near-infrared spectroscopy images taken 3 years after its discovery le
  • Germanium detectors are mostly used for spectroscopy in nuclear physics.
  • Laboratory of spectroscopy in polarized light - UPR 5
  • ental theory of Raman scattering, molecular spectroscopy in gases and liquids, neutron physics and m
  • R. F. Egerton; Electron energy-loss spectroscopy in the electron microscope; Springer, 1996.
  • Spectrochemistry is the application of spectroscopy in any of several fields of chemistry.
  • used as an internal standard for proton NMR spectroscopy in D2O.
  • Caesium nitrate prisms are used in infrared spectroscopy, in x-ray phosphors, and in scintillation c
  • d mass spectrometry, NMR and other forms of spectroscopy) in order to study complex problems in an i
  • He also worked on spectroscopy in the band between far ultraviolet and X-r
  • shift reagent in nuclear magnetic resonance spectroscopy, in order to simultaneously determine absol
  • cific than the general term electromagnetic spectroscopy in that spectrophotometry deals with visibl
  • ne was observed experimentally by microwave spectroscopy in a supersonic jet.
  • As with NMR spectroscopy in general, good resolution requires a high
  • ntist on the use of electron spin resonance spectroscopy in chemistry.
  • Later work involved solar spectroscopy in the near infrared and participation in a
  • 17 for his experimental work in using X-ray spectroscopy in discovering the characteristic X-ray fre
  • 2002 and the 2009 E. Bright Wilson Award in Spectroscopy in 2008 from The American Chemical Society.
  • Becklin's research is infrared imaging and spectroscopy, including the search for brown dwarfs, the
  • solubility in most solvents and vibrational spectroscopy indicate that it is not molecular, but is p
  • chniques such as Nuclear Magnetic Resonance spectroscopy, Infrared spectroscopy, and Circular Dichro
  • Nuclear magnetic resonance (NMR) spectroscopy is a widely used resonance method and ultra
  • ified on the surface of Titania by infrared spectroscopy is carbon dioxide, which is concentrated ma
  • Optics and Spectroscopy is scientific journal, English version of t
  • An excellent introduction to amateur spectroscopy is Astronomical Spectroscopy for Amateurs,
  • Spectroscopy is the study of light through light-matter
  • More generally, integral field spectroscopy is a subset of 3D-imaging techniques (also
  • An example of applying Absorption spectroscopy is the first direct detection and chemical
  • Slitless Spectroscopy is astronomical spectroscopy done without a
  • 31P-NMR spectroscopy is widely used for studies of phospholipid
  • estimated by the color selection, follow-up spectroscopy is performed.
  • essary to obtain a high-precision redshift, spectroscopy is typically much more time-consuming than
  • Reflectance difference spectroscopy is a spectroscopic technique which measures
  • pplying the Beer-Lambert law directly in AA spectroscopy is difficult due to variations in the atomi
  • remittere), in spectroscopy, is the reflection or scattering of light b
  • nd as a result the main difficulty of Raman spectroscopy is separating the weak inelastically scatte
  • The spectroscopy is done by analyzing the different displace
  • Spark or arc atomic emission spectroscopy is used for the analysis of metallic elemen
  • Electron spectroscopy is an analytical technique to study the ele
  • cs and models of stellar evolution, stellar spectroscopy is today used to determine a multitude of p
  • Saturated spectroscopy is the method by which the exact energy of
  • esigning high-resolution NMR probes for NMR spectroscopy: its volume magnetic susceptibility is a ve
  • In X-ray spectroscopy, K-alpha emission lines result when an elec
  • versity and a guest scientist of the Atomic Spectroscopy Laboratory at NIST.
  • ratory in order to create new synthetic and spectroscopy laboratory suites.
  • of Technology appointed him Director of the Spectroscopy Laboratory and in 1954, Professor of Chemis
  • In dielectric spectroscopy, large frequency dependent contributions to
  • His work opened the way to atomic emission spectroscopy, leading eventually to the discovery of the
  • e in the gas phase (determined by microwave spectroscopy, left), the Lewis structure (centre) and th
  • d-state chemistry, polymer physics, polymer spectroscopy, material science and polymer theory.
  • Topical coverage includes nanoprobes, spectroscopy, materials properties, biological systems,
  • e of low cost applications of photoacoustic spectroscopy may be the realization of fully integrated
  • ere reported from Arecibo Observatory radio spectroscopy measurements of the distant starburst galax
  • In general, Doppler spectroscopy measurements do not measure the true mass o
  • gie Planet Search team, who use the Doppler spectroscopy method to detect planets.
  • the viewer's line-of-sight and the Doppler spectroscopy method will not detect the planet at all.
  • 40307 d was discovered through the Doppler spectroscopy method, which functions by measuring the va
  • In traditional arc spectroscopy methods, a sample of the solid was commonly
  • Such techniques include micro Raman spectroscopy, micro infrared spectroscopy and micro LIBS
  • technology, including protein arrays, mass spectroscopy, microanalytic devices, nanotechnology, and
  • In FTIR spectroscopy, Mie scattering causes a broad sinusoidal o
  • ately 3 nanometers or less, making electron spectroscopy most useful to study surfaces of solid mate
  • y, hole burning, photochromism, multiphoton spectroscopy, new techniques for the study of excited st
  • wafer scale integration, Ultra-fast optical spectroscopy, nonlinear optics of semiconductors and org
  • itors in such topics as guided waves, laser spectroscopy, nonlinear optics, quantum optics, lasers,
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