High-energy Nuclear Optics of Polarized Particles:
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| Format: | Elektronisch E-Book |
| Sprache: | English |
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Singapore
World Scientific
2012
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| Online-Zugang: | FAW01 FAW02 Volltext |
| Beschreibung: | 6.3 Positronium (Muonium) in Matter with Polarized Electrons Preface; Acknowledgments; Contents; Introduction; Nuclear Optics of Polarized Matter. Nuclear Pseudomagnetism; 1. Refraction and mirror reflection from a matter-vacuum plane boundary; 1.1 Radiation and Scattering of Waves and Particles; 1.2 Refraction and Mirror Reflection; 1.3 The Optical Theorem; 1.4 Scattering of Waves by a Set of Scatterers; 2. Neutron spin "optical" rotation in matter with polarized nuclei. Nuclear pseudomagnetism; 2.1 Polarized Beams and Polarized Targets; 2.2 Phenomenon of Neutron Spin Precession in a Pseudomagnetic Field of Matter with Polarized Nuclei 2.3 Refraction of Neutrons in a Magnetized Medium2.4 The Schrodinger Equation for a Coherent Neutron Wave Moving in a Polarized Nuclear Target; 2.4.1 Paramagnetic resonance in a nuclear pseudomagnetic field; 2.4.2 Spontaneous radiation of photons accompanying the passage of light through anisotropic matter; 2.5 Neutron and Atomic-Spin Interferometry. Atom (Molecule) Spin Rotation and Oscillation under Refraction in a Constant Electric Field; 2.5.1 Nonorthogonal Quasistationary States; 3. Gamma-optics of polarized matter 3.1 The Phenomenon of Rotation of the Polarization Plane of?-Quanta in Matter with Polarized Electrons. Magnetic X-ray Scattering3.2 Birefringence of?-Quanta in a Target with Polarized Nuclei; 4. Diffraction of particles in polarized crystals; 4.1 Refraction of a Coherent Wave in Polarized Crystals; 4.2 Multifrequency Nuclear Precession of Neutrons in Polarized Crystals with Ferromagnetic and Antiferromagnetic Ordering; 4.3 Magnetic Diffraction of Neutrons; 4.4 Multifrequency Precession of the Neutron Spin in a Uniform Magnetic Field 4.5 The Bragg Case of Neutron Diffraction in Nonmagnetic Crystals in a Magnetic Field4.6 Neutron Spin Precession and Spin Dichroism in Nonmagnetic Nonpolarized Crystals; 4.7 Mirror Reflection Under Diffraction Conditions (Grazing Incidence X-ray Diffraction); 5. Diffraction of neutrons and -quanta in crystals exposed to variable external fields; 5.1 Maxwell Equations and Dielectric Permittivity of Crystals Exposed to a Variable External Field; 5.2 Diffraction of -Quanta in Crystals in a Variable External Field under Resonance Scattering by Nuclei; 5.3 On Refraction in Crystals at a g0 5.4 Scattering of a Monochromatic Plane Wave by a Plate of Matter Exposed to an Ultrasonic Wave5.5 Coherent Acceleration and Polarization of Neutron in Magnetically-Ordered Crystals Illuminated by a Light Wave; 5.6 Nuclear Reactions in a Light Wave; 5.7 Optical Anisotropy of Matter in the Rotating Coordinate System; 5.8 On Emission of Neutrons (?-Quanta) by Nuclei from Crystals; 6. Positronium and muonium spin rotation and oscillations; 6.1 Spin Rotation of an Electron (Atomic) Beam in Magnetized Matter; 6.2 Exchange-Induced Shifts of Atomic Optical Lines in Polarized Gases The various phenomena caused by refraction and diffraction of polarized elementary particles in matter have opened up a new research area in the particle physics: nuclear optics of polarized particles. Effects similar to the well-known optical phenomena such as birefringence and Faraday effects, exist also in particle physics, though the particle wavelength is much less than the distance between atoms of matter. Current knowledge of the quasi-optical effects, which exist for all particles in any wavelength range (and energies from low to extremely high), will enable us to investigate different |
| Beschreibung: | 1 Online-Ressource (641 pages) |
| ISBN: | 9789814324847 9814324841 |
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| 500 | |a 6.3 Positronium (Muonium) in Matter with Polarized Electrons | ||
| 500 | |a Preface; Acknowledgments; Contents; Introduction; Nuclear Optics of Polarized Matter. Nuclear Pseudomagnetism; 1. Refraction and mirror reflection from a matter-vacuum plane boundary; 1.1 Radiation and Scattering of Waves and Particles; 1.2 Refraction and Mirror Reflection; 1.3 The Optical Theorem; 1.4 Scattering of Waves by a Set of Scatterers; 2. Neutron spin "optical" rotation in matter with polarized nuclei. Nuclear pseudomagnetism; 2.1 Polarized Beams and Polarized Targets; 2.2 Phenomenon of Neutron Spin Precession in a Pseudomagnetic Field of Matter with Polarized Nuclei | ||
| 500 | |a 2.3 Refraction of Neutrons in a Magnetized Medium2.4 The Schrodinger Equation for a Coherent Neutron Wave Moving in a Polarized Nuclear Target; 2.4.1 Paramagnetic resonance in a nuclear pseudomagnetic field; 2.4.2 Spontaneous radiation of photons accompanying the passage of light through anisotropic matter; 2.5 Neutron and Atomic-Spin Interferometry. Atom (Molecule) Spin Rotation and Oscillation under Refraction in a Constant Electric Field; 2.5.1 Nonorthogonal Quasistationary States; 3. Gamma-optics of polarized matter | ||
| 500 | |a 3.1 The Phenomenon of Rotation of the Polarization Plane of?-Quanta in Matter with Polarized Electrons. Magnetic X-ray Scattering3.2 Birefringence of?-Quanta in a Target with Polarized Nuclei; 4. Diffraction of particles in polarized crystals; 4.1 Refraction of a Coherent Wave in Polarized Crystals; 4.2 Multifrequency Nuclear Precession of Neutrons in Polarized Crystals with Ferromagnetic and Antiferromagnetic Ordering; 4.3 Magnetic Diffraction of Neutrons; 4.4 Multifrequency Precession of the Neutron Spin in a Uniform Magnetic Field | ||
| 500 | |a 4.5 The Bragg Case of Neutron Diffraction in Nonmagnetic Crystals in a Magnetic Field4.6 Neutron Spin Precession and Spin Dichroism in Nonmagnetic Nonpolarized Crystals; 4.7 Mirror Reflection Under Diffraction Conditions (Grazing Incidence X-ray Diffraction); 5. Diffraction of neutrons and -quanta in crystals exposed to variable external fields; 5.1 Maxwell Equations and Dielectric Permittivity of Crystals Exposed to a Variable External Field; 5.2 Diffraction of -Quanta in Crystals in a Variable External Field under Resonance Scattering by Nuclei; 5.3 On Refraction in Crystals at a g0 | ||
| 500 | |a 5.4 Scattering of a Monochromatic Plane Wave by a Plate of Matter Exposed to an Ultrasonic Wave5.5 Coherent Acceleration and Polarization of Neutron in Magnetically-Ordered Crystals Illuminated by a Light Wave; 5.6 Nuclear Reactions in a Light Wave; 5.7 Optical Anisotropy of Matter in the Rotating Coordinate System; 5.8 On Emission of Neutrons (?-Quanta) by Nuclei from Crystals; 6. Positronium and muonium spin rotation and oscillations; 6.1 Spin Rotation of an Electron (Atomic) Beam in Magnetized Matter; 6.2 Exchange-Induced Shifts of Atomic Optical Lines in Polarized Gases | ||
| 500 | |a The various phenomena caused by refraction and diffraction of polarized elementary particles in matter have opened up a new research area in the particle physics: nuclear optics of polarized particles. Effects similar to the well-known optical phenomena such as birefringence and Faraday effects, exist also in particle physics, though the particle wavelength is much less than the distance between atoms of matter. Current knowledge of the quasi-optical effects, which exist for all particles in any wavelength range (and energies from low to extremely high), will enable us to investigate different | ||
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| 650 | 4 | |a Particles (Nuclear physics) |x Diffraction | |
| 650 | 4 | |a Polarization (Nuclear physics) | |
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Datensatz im Suchindex
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|---|---|
| any_adam_object | |
| author | Baryshevskiĭ, V. G., (Vladimir Grigorʹevich) |
| author_facet | Baryshevskiĭ, V. G., (Vladimir Grigorʹevich) |
| author_role | aut |
| author_sort | Baryshevskiĭ, V. G., (Vladimir Grigorʹevich) |
| author_variant | v g v g b vgvg vgvgb |
| building | Verbundindex |
| bvnumber | BV043081488 |
| collection | ZDB-4-EBA |
| ctrlnum | (OCoLC)794328368 (DE-599)BVBBV043081488 |
| dewey-full | 539.72 |
| dewey-hundreds | 500 - Natural sciences and mathematics |
| dewey-ones | 539 - Modern physics |
| dewey-raw | 539.72 |
| dewey-search | 539.72 |
| dewey-sort | 3539.72 |
| dewey-tens | 530 - Physics |
| discipline | Physik |
| format | Electronic eBook |
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| id | DE-604.BV043081488 |
| illustrated | Not Illustrated |
| indexdate | 2024-07-10T07:16:51Z |
| institution | BVB |
| isbn | 9789814324847 9814324841 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-028505680 |
| oclc_num | 794328368 |
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| owner | DE-1046 DE-1047 |
| owner_facet | DE-1046 DE-1047 |
| physical | 1 Online-Ressource (641 pages) |
| psigel | ZDB-4-EBA ZDB-4-EBA FAW_PDA_EBA |
| publishDate | 2012 |
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| publisher | World Scientific |
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| spelling | Baryshevskiĭ, V. G., (Vladimir Grigorʹevich) Verfasser aut High-energy Nuclear Optics of Polarized Particles Singapore World Scientific 2012 1 Online-Ressource (641 pages) txt rdacontent c rdamedia cr rdacarrier 6.3 Positronium (Muonium) in Matter with Polarized Electrons Preface; Acknowledgments; Contents; Introduction; Nuclear Optics of Polarized Matter. Nuclear Pseudomagnetism; 1. Refraction and mirror reflection from a matter-vacuum plane boundary; 1.1 Radiation and Scattering of Waves and Particles; 1.2 Refraction and Mirror Reflection; 1.3 The Optical Theorem; 1.4 Scattering of Waves by a Set of Scatterers; 2. Neutron spin "optical" rotation in matter with polarized nuclei. Nuclear pseudomagnetism; 2.1 Polarized Beams and Polarized Targets; 2.2 Phenomenon of Neutron Spin Precession in a Pseudomagnetic Field of Matter with Polarized Nuclei 2.3 Refraction of Neutrons in a Magnetized Medium2.4 The Schrodinger Equation for a Coherent Neutron Wave Moving in a Polarized Nuclear Target; 2.4.1 Paramagnetic resonance in a nuclear pseudomagnetic field; 2.4.2 Spontaneous radiation of photons accompanying the passage of light through anisotropic matter; 2.5 Neutron and Atomic-Spin Interferometry. Atom (Molecule) Spin Rotation and Oscillation under Refraction in a Constant Electric Field; 2.5.1 Nonorthogonal Quasistationary States; 3. Gamma-optics of polarized matter 3.1 The Phenomenon of Rotation of the Polarization Plane of?-Quanta in Matter with Polarized Electrons. Magnetic X-ray Scattering3.2 Birefringence of?-Quanta in a Target with Polarized Nuclei; 4. Diffraction of particles in polarized crystals; 4.1 Refraction of a Coherent Wave in Polarized Crystals; 4.2 Multifrequency Nuclear Precession of Neutrons in Polarized Crystals with Ferromagnetic and Antiferromagnetic Ordering; 4.3 Magnetic Diffraction of Neutrons; 4.4 Multifrequency Precession of the Neutron Spin in a Uniform Magnetic Field 4.5 The Bragg Case of Neutron Diffraction in Nonmagnetic Crystals in a Magnetic Field4.6 Neutron Spin Precession and Spin Dichroism in Nonmagnetic Nonpolarized Crystals; 4.7 Mirror Reflection Under Diffraction Conditions (Grazing Incidence X-ray Diffraction); 5. Diffraction of neutrons and -quanta in crystals exposed to variable external fields; 5.1 Maxwell Equations and Dielectric Permittivity of Crystals Exposed to a Variable External Field; 5.2 Diffraction of -Quanta in Crystals in a Variable External Field under Resonance Scattering by Nuclei; 5.3 On Refraction in Crystals at a g0 5.4 Scattering of a Monochromatic Plane Wave by a Plate of Matter Exposed to an Ultrasonic Wave5.5 Coherent Acceleration and Polarization of Neutron in Magnetically-Ordered Crystals Illuminated by a Light Wave; 5.6 Nuclear Reactions in a Light Wave; 5.7 Optical Anisotropy of Matter in the Rotating Coordinate System; 5.8 On Emission of Neutrons (?-Quanta) by Nuclei from Crystals; 6. Positronium and muonium spin rotation and oscillations; 6.1 Spin Rotation of an Electron (Atomic) Beam in Magnetized Matter; 6.2 Exchange-Induced Shifts of Atomic Optical Lines in Polarized Gases The various phenomena caused by refraction and diffraction of polarized elementary particles in matter have opened up a new research area in the particle physics: nuclear optics of polarized particles. Effects similar to the well-known optical phenomena such as birefringence and Faraday effects, exist also in particle physics, though the particle wavelength is much less than the distance between atoms of matter. Current knowledge of the quasi-optical effects, which exist for all particles in any wavelength range (and energies from low to extremely high), will enable us to investigate different High spin physics Physics Science SCIENCE / Physics / Nuclear bisacsh Naturwissenschaft Particles (Nuclear physics) Diffraction Polarization (Nuclear physics) http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=457169 Aggregator Volltext |
| spellingShingle | Baryshevskiĭ, V. G., (Vladimir Grigorʹevich) High-energy Nuclear Optics of Polarized Particles High spin physics Physics Science SCIENCE / Physics / Nuclear bisacsh Naturwissenschaft Particles (Nuclear physics) Diffraction Polarization (Nuclear physics) |
| title | High-energy Nuclear Optics of Polarized Particles |
| title_auth | High-energy Nuclear Optics of Polarized Particles |
| title_exact_search | High-energy Nuclear Optics of Polarized Particles |
| title_full | High-energy Nuclear Optics of Polarized Particles |
| title_fullStr | High-energy Nuclear Optics of Polarized Particles |
| title_full_unstemmed | High-energy Nuclear Optics of Polarized Particles |
| title_short | High-energy Nuclear Optics of Polarized Particles |
| title_sort | high energy nuclear optics of polarized particles |
| topic | High spin physics Physics Science SCIENCE / Physics / Nuclear bisacsh Naturwissenschaft Particles (Nuclear physics) Diffraction Polarization (Nuclear physics) |
| topic_facet | High spin physics Physics Science SCIENCE / Physics / Nuclear Naturwissenschaft Particles (Nuclear physics) Diffraction Polarization (Nuclear physics) |
| url | http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=457169 |
| work_keys_str_mv | AT baryshevskiivgvladimirgrigorʹevich highenergynuclearopticsofpolarizedparticles |