Results 241 to 250 of about 285,303 (294)
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Conduction Electron Spin Resonance
Physical Review, 1966We have calculated (using a simple theory) the paramagnetic-resonance absorption by conduction electrons in a thin metallic sample, thus extending the earlier work of Dyson. Our results are for a metal sample of arbitrary thickness, with a static magnetic field ${\mathcal{H}}_{0}$ at arbitrary angle with respect to the sample surface, and under either ...
M. Lampe, P. M. Platzman
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Temperature of spin-spin interactions in electron spin resonance
Uspekhi Fizicheskih Nauk, 1972A review is presented of the theoretical and experimental papers on spin resonance, in which the concept of the reservoir of spin-spin interactions in a solid is used. We explain the main ideas connected with the introduction of two spin temperatures, TZ and TSS, to describe quasi-equilibrium in the Zeeman and spin-spin subsystems (Provotorov's theory);
V A Atsarkin, M I Rodak
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ELECTRON-SPIN RESONANCE SPECTROSCOPY
2005Electron-spin resonance (ESR) spectroscopy, otherwise known as electron paramagnetic resonance (EPR) spectroscopy, is a nondestructive, noninvasive, highly sensitive and accurate analytical technique that can detect and characterize chemical species possessing unpaired electrons, i.e., paramagnetic.
Senesi N, Senesi G S
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Tanpakushitsu kakusan koso. Protein, nucleic acid, enzyme, 1986
AbstractElectron spin resonance (ESR), or electron paramagnetic resonance (EPR), is an analytical technique that can extract a great deal of information from any material containing unpaired electrons. This article explains how ESR works and where it applies in materials characterization. It describes a typical ESR spectrometer and explains how to tune
Charles P. Poole, Horatio A. Farach
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AbstractElectron spin resonance (ESR), or electron paramagnetic resonance (EPR), is an analytical technique that can extract a great deal of information from any material containing unpaired electrons. This article explains how ESR works and where it applies in materials characterization. It describes a typical ESR spectrometer and explains how to tune
Charles P. Poole, Horatio A. Farach
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Electron Spin Resonance: Spin Labels
1981In general biological membranes possess no intrinsic paramagnetism and hence in the unlabeled state do not give rise to an electron spin resonance (ESR) spectrum. The introduction of a stable free radical (“spin label”) thus enables one to use ESR spectroscopy to study specific environments within the membrane.
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1987
Electron spin resonance (ESR), sometimes called electron paramagnetic resonance (EPR), is a technique for studying the structure and properties of species containing unpaired electrons. Thus it is restricted to free radicals, paramagnetic metal ions and molecules in a triplet electronic state.
M. H. Gordon, R. Macrae
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Electron spin resonance (ESR), sometimes called electron paramagnetic resonance (EPR), is a technique for studying the structure and properties of species containing unpaired electrons. Thus it is restricted to free radicals, paramagnetic metal ions and molecules in a triplet electronic state.
M. H. Gordon, R. Macrae
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Journal of Molecular Structure, 1989
Specialist Periodical Reports provide systematic and detailed review coverage of progress in the major areas of chemical research. Written by experts in their specialist fields the series creates a unique service for the active research chemist, supplying regular critical in-depth accounts of progress in particular areas of chemistry. For over 80 years
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Specialist Periodical Reports provide systematic and detailed review coverage of progress in the major areas of chemical research. Written by experts in their specialist fields the series creates a unique service for the active research chemist, supplying regular critical in-depth accounts of progress in particular areas of chemistry. For over 80 years
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1996
Specialist Periodical Reports provide systematic and detailed review coverage of progress in the major areas of chemical research. Written by experts in their specialist fields the series creates a unique service for the active research chemist, supplying regular critical in-depth accounts of progress in particular areas of chemistry. For over 80 years
A G Davies +13 more
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Specialist Periodical Reports provide systematic and detailed review coverage of progress in the major areas of chemical research. Written by experts in their specialist fields the series creates a unique service for the active research chemist, supplying regular critical in-depth accounts of progress in particular areas of chemistry. For over 80 years
A G Davies +13 more
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1992
Specialist Periodical Reports provide systematic and detailed review coverage of progress in the major areas of chemical research. Written by experts in their specialist fields the series creates a unique service for the active research chemist, supplying regular critical in-depth accounts of progress in particular areas of chemistry. For over 80 years
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Specialist Periodical Reports provide systematic and detailed review coverage of progress in the major areas of chemical research. Written by experts in their specialist fields the series creates a unique service for the active research chemist, supplying regular critical in-depth accounts of progress in particular areas of chemistry. For over 80 years
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2021
The analysis of the preceding Chapter was for a constant magnetic field. From Exercise 14.9, we see that the magnetic field is very large (> 1 T) for the Zeeman splitting to exceed the thermal energy. This is desired to prevent unwanted thermal excitation between the Zeeman split energy levels from affecting our qubit states.
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The analysis of the preceding Chapter was for a constant magnetic field. From Exercise 14.9, we see that the magnetic field is very large (> 1 T) for the Zeeman splitting to exceed the thermal energy. This is desired to prevent unwanted thermal excitation between the Zeeman split energy levels from affecting our qubit states.
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