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Accelerator-Driven System at Kyoto University Critical Assembly

Pyeon Cheol Ho

Springer Nature, 2021

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Accelerator-Driven System at Kyoto University Critical Assembly

Pyŏn Ch'ŏr-ho

Springer Nature, 2021

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Homogeneous Catalysis and Mechanisms in Water and Biphasic Media / Luca Gonsalvi

Gonsalvi Luca

MDPI - Multidisciplinary Digital Publishing Institute, 2019

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Magnetism and Accelerator-Based Light Sources : Proceedings of the 7th International School ''Synchrotron Radiation and Magnetism'', Mittelwihr (France) 2018

Bulou Hervé

Springer Nature, 2021

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Magnetism and Accelerator-Based Light Sources : Proceedings of the 7th International School ''Synchrotron Radiation and Magnetism'', Mittelwihr (France) 2018

Bulou H (Hervé)

Springer Nature, 2021

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Molecules in Superfluid Helium Nanodroplets [[electronic resource] ] : Spectroscopy, Structure, and Dynamics

Slenczka Alkwin

Cham, : Springer International Publishing AG, 2022

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Molecules in Superfluid Helium Nanodroplets : Spectroscopy, Structure, and Dynamics

Slenczka Alkwin

Cham, : Springer International Publishing AG, 2022

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Vermittlungsarbeit : Zur Untersuchung und Verwertung biologischer Materialien in der kommerziellen Naturstoffchemie

Angerer Klaus

Nomos Verlagsgesellschaft mbH & Co. KG, 2021

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Autore	Pyeon Cheol Ho
Pubbl/distr/stampa	Springer Nature, 2021
Descrizione fisica	1 online resource (353 pages)
Soggetto topico	Atomic & molecular physics Nuclear power & engineering Spectrum analysis, spectrochemistry, mass spectrometry Particle & high-energy physics
Soggetto non controllato	Nuclear Physics, Heavy Ions, Hadrons Nuclear Energy Nuclear Chemistry Particle Acceleration and Detection, Beam Physics Nuclear Physics Accelerator Physics Open Access Reactor Physics Experiments ADS KUCA Subcriticality Measurement Kinetics Parameter Estimation in Subcritical State Nuclear Transmutation Uncertainty Quantification Atomic & molecular physics Nuclear power & engineering Nuclear chemistry, photochemistry & radiation Particle & high-energy physics
ISBN	981-16-0344-8
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Intro -- Preface -- Contents -- Contributors -- 1 Introduction -- 1.1 Kyoto University Critical Assembly -- 1.1.1 KUCA Facility -- 1.1.2 Solid-Moderated and Solid-Reflected Cores -- 1.1.3 Light-Water-Moderated and Light-Water-Reflected Core -- 1.1.4 Pulsed-Neutron Generator -- 1.1.5 Fixed-Field Alternating Gradient Accelerator -- 1.2 Accelerator-Driven System -- 1.2.1 Overview of Research and Development -- 1.2.2 Feasibility Study at KUCA -- References -- 2 Subcriticality -- 2.1 Feynman-α and Rossi-α Analyses -- 2.1.1 Experimental Settings -- 2.1.2 Formulae for Data Analyses -- 2.1.3 Results and Discussion -- 2.2 Power Spectral Analyses -- 2.2.1 Experimental Settings -- 2.2.2 Formula for Power Spectral Analyses -- 2.2.3 Results and Discussion -- 2.3 Beam Trip and Restart Methods -- 2.3.1 Experimental Settings -- 2.3.2 Data Analyses Method -- 2.3.3 Results and Discussion -- 2.4 Conclusion -- References -- 3 Reactor Kinetics -- 3.1 α-Fitting Method -- 3.1.1 Experimental Settings -- 3.1.2 Numerical Simulations -- 3.1.3 Results and Discussion -- 3.2 Pulsed-Neutron Source Method -- 3.2.1 Experimental Settings -- 3.2.2 Results and Discussion -- 3.3 Inverse Kinetic Method -- 3.3.1 Theoretical Background -- 3.3.2 Experimental Settings -- 3.3.3 Transient Analyses -- 3.4 Conclusion -- References -- 4 Effective Delayed Neutron Fraction -- 4.1 Dependency of External Neutron Source -- 4.1.1 Experimental Settings -- 4.1.2 Numerical Simulations -- 4.1.3 k-Ratio Method -- 4.2 Measurement -- 4.2.1 Nelson Number Method -- 4.2.2 Experimental Settings -- 4.2.3 Results and Discussion -- 4.3 Evaluation of βeff/Λ -- 4.3.1 Experimental Settings -- 4.3.2 Kinetics Parameters -- 4.3.3 Results and Discussion -- 4.4 Neutron Generation Time -- 4.4.1 Experimental Settings -- 4.4.2 Results and Discussion -- 4.5 Conclusion -- References -- 5 Neutron Spectrum. 5.1 Subcritical Multiplication Factor -- 5.1.1 Theoretical Background -- 5.1.2 Characteristics of the Target -- 5.1.3 Effects of Neutron Spectrum -- 5.2 Threshold Energy Reactions -- 5.2.1 Foil Activation Method -- 5.2.2 Activation Foils -- 5.3 Spectrum Index -- 5.3.1 Cd Ratio -- 5.3.2 In Ratio -- 5.4 Spallation Neutrons -- 5.4.1 Neutron Spectrum Analyses -- 5.4.2 Reaction Rates -- 5.5 Conclusion -- References -- 6 Nuclear Transmutation of Minor Actinide -- 6.1 Integral Experiments at Critical State -- 6.1.1 Critical Irradiation Experiments -- 6.1.2 Experimental Analyses -- 6.1.3 Discussion -- 6.2 ADS Irradiation at Subcritical State -- 6.2.1 Experimental Settings -- 6.2.2 Demonstration of Nuclear Transmutation -- 6.3 Conclusion -- References -- 7 Neutronics of Lead and Bismuth -- 7.1 Sample Reactivity Worth Experiments -- 7.1.1 Core Configuration -- 7.1.2 Experimental Settings -- 7.2 Monte Carlo Analyses -- 7.2.1 Evaluation Method -- 7.2.2 Lead Sample Reactivity Worth -- 7.2.3 Bismuth Sample Reactivity Worth -- 7.3 Sensitivity Coefficients -- 7.3.1 Theoretical Background -- 7.3.2 Lead Isotopes -- 7.3.3 Bismuth Isotope -- 7.4 Uncertainty Quantification -- 7.4.1 Theoretical Background -- 7.4.2 Lead Isotopes -- 7.4.3 Bismuth Isotope -- 7.5 Conclusion -- References -- 8 Sensitivity and Uncertainty of Criticality -- 8.1 Experimental Settings -- 8.1.1 Core Configuration -- 8.1.2 Reactivity Measurements -- 8.2 Criticality -- 8.2.1 Numerical Simulations -- 8.2.2 Sensitivity and Uncertainty -- 8.2.3 Results and Discussion -- 8.3 Benchmarks -- 8.3.1 Experimental Analyses -- 8.3.2 Uncertainty -- 8.4 Conclusion -- References -- Appendix A1: Experimental Benchmarks on ADS at Kyoto University Critical Assembly -- A1.1 Experimental Settings of ADS Benchmarks -- A1.1.1 Core Components -- A1.1.2 Atomic Number Density of Core Elements -- References. Appendix A2: 235U-Fueled and Pb-Bi-Zoned ADS Core -- A2.1 Pb-Bi Target -- A2.1.1 Core Configurations -- A2.1.2 Results of Experiments -- A2.1.2.1 Reaction Rate Distribution -- A2.1.2.2 PNS and Feynman-α Methods -- A2.2 Subcriticality Measurements -- A2.2.1 Core Configurations -- A2.2.2 Results of Experiments -- A2.2.3 PNS and Feynman-α Methods -- A2.3 Reaction Rates -- A2.3.1 Core Configurations -- A2.3.2 Reaction Rate Distributions -- A2.3.3 Reaction Rates of Activation Foils -- References -- Appendix A3: 235U-Fueled and Pb-Zoned ADS Core -- A3.1 Core Configurations -- A3.1.1 ADS with 14 MeV Neutrons -- A3.1.2 ADS with 100 MeV Protons -- A3.2 Kinetics Parameters -- A3.2.1 ADS with 14 MeV Neutrons -- A3.2.1.1 Core Condition at Critical State -- A3.2.1.2 Case D1 (4560 HEU Plates) -- A3.2.1.3 Case D2 (4400 HEU Plates) -- A3.2.1.4 Case D3 (4320 HEU Plates) -- A3.2.1.5 Case D4 (4200 HEU Plates) -- A3.2.1.6 Case D5 (4080 HEU Plates) -- A3.2.1.7 Case D6 (3840 HEU Plates) -- A3.2.2 ADS with 100 MeV Protons -- A3.2.2.1 Core Condition at Critical State -- A3.2.2.2 Case F1 (4560 HEU Plates) -- A3.2.2.3 Case F2 (4440 HEU Plates) -- A3.2.2.4 Case F3 (4320 HEU Plates) -- A3.2.2.5 Case F4 (4200 HEU Plates) -- A3.2.2.6 Case F5 (4080 HEU Plates) -- A3.2.2.7 Case F6 (3960 HEU Plates) -- A3.2.2.8 Case F7 (3840 HEU Plates) -- A3.3 Reaction Rates -- A3.3.1 Core Configurations -- A3.3.2 Reaction Rate Distribution -- References -- Appendix A4: 235U-Fueled ADS Core in Medium-Fast Spectrum -- A4.1 Core Configurations -- A4.1.1 ADS with 14 MeV Neutrons -- A4.1.2 ADS with 100 MeV Protons -- A4.2 Results of Experiments -- A4.2.1 Criticality and Control Rod Worth -- A4.2.2 PNS and Feynman-α Methods -- A4.3 Kinetic Parameters -- A4.3.1 ADS with 14 MeV Neutrons -- A4.3.2 ADS with 100 MeV Protons -- A4.4 Reaction Rates -- A4.4.1 Core Configurations. A4.4.2 Reaction Rate Distributions -- A4.4.3 Reaction Rates of Activation Foils -- References -- Appendix A5: 232Th-Fueled ADS Core -- A5.1 Core Configurations -- A5.2 Results of Experiments -- A5.2.1 Reaction Rate Distributions -- A5.2.2 PNS and Feynman-α Methods -- References.
Record Nr.	UNISA-996466748203316

Autore	Pyŏn Ch'ŏr-ho
Pubbl/distr/stampa	Springer Nature, 2021
Descrizione fisica	1 online resource (353 pages)
Soggetto topico	Atomic & molecular physics Nuclear power & engineering Spectrum analysis, spectrochemistry, mass spectrometry Particle & high-energy physics
Soggetto non controllato	Nuclear Physics, Heavy Ions, Hadrons Nuclear Energy Nuclear Chemistry Particle Acceleration and Detection, Beam Physics Nuclear Physics Accelerator Physics Open Access Reactor Physics Experiments ADS KUCA Subcriticality Measurement Kinetics Parameter Estimation in Subcritical State Nuclear Transmutation Uncertainty Quantification Atomic & molecular physics Nuclear power & engineering Nuclear chemistry, photochemistry & radiation Particle & high-energy physics
ISBN	981-16-0344-8
Classificazione	SCI013060SCI051000TEC028000
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Intro -- Preface -- Contents -- Contributors -- 1 Introduction -- 1.1 Kyoto University Critical Assembly -- 1.1.1 KUCA Facility -- 1.1.2 Solid-Moderated and Solid-Reflected Cores -- 1.1.3 Light-Water-Moderated and Light-Water-Reflected Core -- 1.1.4 Pulsed-Neutron Generator -- 1.1.5 Fixed-Field Alternating Gradient Accelerator -- 1.2 Accelerator-Driven System -- 1.2.1 Overview of Research and Development -- 1.2.2 Feasibility Study at KUCA -- References -- 2 Subcriticality -- 2.1 Feynman-α and Rossi-α Analyses -- 2.1.1 Experimental Settings -- 2.1.2 Formulae for Data Analyses -- 2.1.3 Results and Discussion -- 2.2 Power Spectral Analyses -- 2.2.1 Experimental Settings -- 2.2.2 Formula for Power Spectral Analyses -- 2.2.3 Results and Discussion -- 2.3 Beam Trip and Restart Methods -- 2.3.1 Experimental Settings -- 2.3.2 Data Analyses Method -- 2.3.3 Results and Discussion -- 2.4 Conclusion -- References -- 3 Reactor Kinetics -- 3.1 α-Fitting Method -- 3.1.1 Experimental Settings -- 3.1.2 Numerical Simulations -- 3.1.3 Results and Discussion -- 3.2 Pulsed-Neutron Source Method -- 3.2.1 Experimental Settings -- 3.2.2 Results and Discussion -- 3.3 Inverse Kinetic Method -- 3.3.1 Theoretical Background -- 3.3.2 Experimental Settings -- 3.3.3 Transient Analyses -- 3.4 Conclusion -- References -- 4 Effective Delayed Neutron Fraction -- 4.1 Dependency of External Neutron Source -- 4.1.1 Experimental Settings -- 4.1.2 Numerical Simulations -- 4.1.3 k-Ratio Method -- 4.2 Measurement -- 4.2.1 Nelson Number Method -- 4.2.2 Experimental Settings -- 4.2.3 Results and Discussion -- 4.3 Evaluation of βeff/Λ -- 4.3.1 Experimental Settings -- 4.3.2 Kinetics Parameters -- 4.3.3 Results and Discussion -- 4.4 Neutron Generation Time -- 4.4.1 Experimental Settings -- 4.4.2 Results and Discussion -- 4.5 Conclusion -- References -- 5 Neutron Spectrum. 5.1 Subcritical Multiplication Factor -- 5.1.1 Theoretical Background -- 5.1.2 Characteristics of the Target -- 5.1.3 Effects of Neutron Spectrum -- 5.2 Threshold Energy Reactions -- 5.2.1 Foil Activation Method -- 5.2.2 Activation Foils -- 5.3 Spectrum Index -- 5.3.1 Cd Ratio -- 5.3.2 In Ratio -- 5.4 Spallation Neutrons -- 5.4.1 Neutron Spectrum Analyses -- 5.4.2 Reaction Rates -- 5.5 Conclusion -- References -- 6 Nuclear Transmutation of Minor Actinide -- 6.1 Integral Experiments at Critical State -- 6.1.1 Critical Irradiation Experiments -- 6.1.2 Experimental Analyses -- 6.1.3 Discussion -- 6.2 ADS Irradiation at Subcritical State -- 6.2.1 Experimental Settings -- 6.2.2 Demonstration of Nuclear Transmutation -- 6.3 Conclusion -- References -- 7 Neutronics of Lead and Bismuth -- 7.1 Sample Reactivity Worth Experiments -- 7.1.1 Core Configuration -- 7.1.2 Experimental Settings -- 7.2 Monte Carlo Analyses -- 7.2.1 Evaluation Method -- 7.2.2 Lead Sample Reactivity Worth -- 7.2.3 Bismuth Sample Reactivity Worth -- 7.3 Sensitivity Coefficients -- 7.3.1 Theoretical Background -- 7.3.2 Lead Isotopes -- 7.3.3 Bismuth Isotope -- 7.4 Uncertainty Quantification -- 7.4.1 Theoretical Background -- 7.4.2 Lead Isotopes -- 7.4.3 Bismuth Isotope -- 7.5 Conclusion -- References -- 8 Sensitivity and Uncertainty of Criticality -- 8.1 Experimental Settings -- 8.1.1 Core Configuration -- 8.1.2 Reactivity Measurements -- 8.2 Criticality -- 8.2.1 Numerical Simulations -- 8.2.2 Sensitivity and Uncertainty -- 8.2.3 Results and Discussion -- 8.3 Benchmarks -- 8.3.1 Experimental Analyses -- 8.3.2 Uncertainty -- 8.4 Conclusion -- References -- Appendix A1: Experimental Benchmarks on ADS at Kyoto University Critical Assembly -- A1.1 Experimental Settings of ADS Benchmarks -- A1.1.1 Core Components -- A1.1.2 Atomic Number Density of Core Elements -- References. Appendix A2: 235U-Fueled and Pb-Bi-Zoned ADS Core -- A2.1 Pb-Bi Target -- A2.1.1 Core Configurations -- A2.1.2 Results of Experiments -- A2.1.2.1 Reaction Rate Distribution -- A2.1.2.2 PNS and Feynman-α Methods -- A2.2 Subcriticality Measurements -- A2.2.1 Core Configurations -- A2.2.2 Results of Experiments -- A2.2.3 PNS and Feynman-α Methods -- A2.3 Reaction Rates -- A2.3.1 Core Configurations -- A2.3.2 Reaction Rate Distributions -- A2.3.3 Reaction Rates of Activation Foils -- References -- Appendix A3: 235U-Fueled and Pb-Zoned ADS Core -- A3.1 Core Configurations -- A3.1.1 ADS with 14 MeV Neutrons -- A3.1.2 ADS with 100 MeV Protons -- A3.2 Kinetics Parameters -- A3.2.1 ADS with 14 MeV Neutrons -- A3.2.1.1 Core Condition at Critical State -- A3.2.1.2 Case D1 (4560 HEU Plates) -- A3.2.1.3 Case D2 (4400 HEU Plates) -- A3.2.1.4 Case D3 (4320 HEU Plates) -- A3.2.1.5 Case D4 (4200 HEU Plates) -- A3.2.1.6 Case D5 (4080 HEU Plates) -- A3.2.1.7 Case D6 (3840 HEU Plates) -- A3.2.2 ADS with 100 MeV Protons -- A3.2.2.1 Core Condition at Critical State -- A3.2.2.2 Case F1 (4560 HEU Plates) -- A3.2.2.3 Case F2 (4440 HEU Plates) -- A3.2.2.4 Case F3 (4320 HEU Plates) -- A3.2.2.5 Case F4 (4200 HEU Plates) -- A3.2.2.6 Case F5 (4080 HEU Plates) -- A3.2.2.7 Case F6 (3960 HEU Plates) -- A3.2.2.8 Case F7 (3840 HEU Plates) -- A3.3 Reaction Rates -- A3.3.1 Core Configurations -- A3.3.2 Reaction Rate Distribution -- References -- Appendix A4: 235U-Fueled ADS Core in Medium-Fast Spectrum -- A4.1 Core Configurations -- A4.1.1 ADS with 14 MeV Neutrons -- A4.1.2 ADS with 100 MeV Protons -- A4.2 Results of Experiments -- A4.2.1 Criticality and Control Rod Worth -- A4.2.2 PNS and Feynman-α Methods -- A4.3 Kinetic Parameters -- A4.3.1 ADS with 14 MeV Neutrons -- A4.3.2 ADS with 100 MeV Protons -- A4.4 Reaction Rates -- A4.4.1 Core Configurations. A4.4.2 Reaction Rate Distributions -- A4.4.3 Reaction Rates of Activation Foils -- References -- Appendix A5: 232Th-Fueled ADS Core -- A5.1 Core Configurations -- A5.2 Results of Experiments -- A5.2.1 Reaction Rate Distributions -- A5.2.2 PNS and Feynman-α Methods -- References.
Record Nr.	UNINA-9910473449803321

Autore	Bulou Hervé
Pubbl/distr/stampa	Springer Nature, 2021
Descrizione fisica	1 online resource (219 pages)
Altri autori (Persone)	JolyLoïc MariotJean-Michel ScheurerFabrice
Collana	Springer Proceedings in Physics
Soggetto topico	Spectrum analysis, spectrochemistry, mass spectrometry Atomic & molecular physics Optical physics Fluid mechanics Circuits & components
Soggetto non controllato	Spectroscopy and Microscopy Atomic, Molecular, Optical and Plasma Physics Optics, Lasers, Photonics, Optical Devices Condensed Matter Physics Magnetism, Magnetic Materials Semiconductors X-Ray Spectroscopy Synchrotron Techniques Laser-Matter Interaction Strongly Correlated Systems Magnetism x-ray light sources x-ray scattering spintronics Open Access Gauge invariance in spectroscopy molecular magnestism magnetic semiconductors Spectrum analysis, spectrochemistry, mass spectrometry Scientific equipment, experiments & techniques Atomic & molecular physics Optical physics Applied optics Materials / States of matter Electricity, electromagnetism & magnetism Electronic devices & materials
ISBN	3-030-64623-8
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Intro -- Foreword -- Preface -- Teachers -- Scientific Committee -- Acknowledgements -- Contents -- Contributors -- 1 X-Ray Sources at Large-Scale Facilities -- 1.1 Introduction -- 1.2 A Brief Description of Synchrotrons -- 1.2.1 Introduction -- 1.2.2 The Lorentz Factor -- 1.2.3 Dipole Radiation and Synchrotron Radiation -- 1.2.4 Spectral Flux, Emittance, and Brilliance -- 1.2.5 The Radio-Frequency Power Supply -- 1.2.6 Radiation Equilibrium -- 1.2.7 Coherence -- 1.3 Sources of Synchrotron Radiation -- 1.3.1 Bending Magnets and Wigglers -- 1.3.2 Undulators -- 1.3.3 Polarization of Synchrotron Radiation -- 1.4 Diffraction-Limited Storage Rings -- 1.5 X-Ray Free-Electron Lasers -- 1.5.1 XFEL Architecture -- 1.5.2 The SASE Process -- 1.5.3 Concluding Remarks -- 1.6 Summary -- References -- 2 Concepts in Magnetism -- 2.1 Introduction -- 2.2 Exchange -- 2.2.1 Direct Exchange -- 2.2.2 Indirect Exchange -- 2.2.3 Superexchange -- 2.3 Consequences of the Heisenberg Exchange Interaction -- 2.3.1 Two Interacting Spin-12 Particles -- 2.3.2 A Chain of Spins -- 2.3.3 Three Spins -- 2.4 Orbitals -- 2.4.1 Transition Metal Ions -- 2.4.2 Spin-Orbit Interaction and Crystal Fields -- 2.4.3 Jahn-Teller Effect -- 2.5 Conclusion -- References -- 3 Electronic Structure Theory for X-Ray Absorption and Photoemission Spectroscopy -- 3.1 Introduction -- 3.2 Light-Matter Interaction -- 3.3 Ground State Electronic Structure Theory -- 3.3.1 Hartree-Fock Approximation -- 3.3.2 Density Functional Theory -- 3.4 Absorption Spectra in the Independent Particle Approximation -- 3.4.1 Dipole Selection Rules and Density of States -- 3.5 Absorption Spectra in Linear Response TDDFT -- 3.5.1 Time-Dependent Density Functional Theory -- 3.5.2 Linear Response Theory -- 3.5.3 Absorption Spectra -- 3.6 Photoemission Spectroscopy -- 3.6.1 Angle-Resolved Photoemission Spectroscopy. 3.7 Quasiparticle Theory -- 3.7.1 Green's Functions -- 3.7.2 GW Approximation -- 3.7.3 Bethe-Salpeter Equation -- 3.7.4 Static and Dynamical Mean-Field Theory -- 3.8 Conclusions -- References -- 4 X-ray Dichroisms in Spherical Tensor and Green's Function Formalism -- 4.1 Introduction -- 4.1.1 The X-ray Absorption Cross Section -- 4.1.2 Definition of Dichroisms -- 4.1.3 The Many-Body Problem in Spectra Calculations -- 4.1.4 Codes for Ligand-Field Multiplet Calculations -- 4.2 Spherical Tensor Expansion of the XAS Cross Section -- 4.2.1 The Case of Electric Dipole Transitions -- 4.2.2 The Case of Electric Quadrupole Transitions -- 4.2.3 Term a=0 -- 4.2.4 Term a=1 -- 4.2.5 Term a=2 -- 4.2.6 Term a=3 -- 4.2.7 Term a=4 -- 4.3 Conclusion -- References -- 5 Spintronics and Synchrotron Radiation -- 5.1 General Introduction to Spintronics: From Magnetoresistive Effects to the Physics of Spin-Transfer Phenomena -- 5.1.1 Giant Magnetoresistance: An Historical Point of View -- 5.1.2 Tunnelling Magnetoresistance -- 5.1.3 Magnetization Manipulation without Magnetic Fields -- 5.1.4 Summary -- 5.2 Examples of Synchrotron Radiation Contribution to Spintronics -- 5.2.1 Voltage Control of Magnetism -- 5.2.2 Spintronics with Pure Spin Current -- 5.2.3 Current-Induced Magnetization Dynamics -- 5.3 Conclusion -- References -- 6 p-Wave Superconductivity and d-Vector Representation -- 6.1 Introduction -- 6.2 Odd-Parity Pairing: BCS Wave Function and Order Parameter -- 6.3 Vectors and Cayley-Klein Representation -- 6.3.1 Position of the Problem -- 6.3.2 Useful Formula for Pauli Matrices -- 6.3.3 Rotation of a 3D Vector: Cayley-Klein Relation -- 6.4 d-Vector Representation -- 6.5 Behaviour under Rotations -- 6.5.1 Rotation in Spin Space -- 6.5.2 Rotation in Real Space -- 6.5.3 Change of Quantization Axis: Application to ESP States. 6.6 Some Uses of the d-Vector Representation -- 6.6.1 Amplitude of the d-Vector -- 6.6.2 Spin Direction -- 6.6.3 Non-unitary States -- 6.6.4 Orbital Moment -- 6.6.5 Excitation Energy of Quasiparticles -- 6.7 The Spin-Orbit Issue -- 6.7.1 Spin-Orbit and the Superconducting Order Parameter -- 6.7.2 Anisotropy of the Susceptibility for the Strong Spin-Orbit Case -- 6.8 d d d d-vector Representation of Some Known (or Suspected) p-Wave Superconductors -- 6.8.1 Phases of Superfluid 3He -- 6.8.2 UPt3 and Sr2RuO4 -- 6.9 Ferromagnetic Superconductors -- 6.9.1 ESP States -- 6.9.2 Symmetries -- 6.9.3 Microscopic Model -- 6.10 UTe2 -- 6.11 Proofs and Exercise Solutions -- 6.11.1 Proof of the Cayley-Klein Relation -- 6.11.2 Conservation of the Scalar Product under Rotation with the Definition (6.11) -- 6.11.3 Conservation of the Cross Product under Rotation with the Definition (6.11) -- 6.11.4 Rotation of the d d d d-Vector of a Simple ``Up-Up'' State -- 6.11.5 Equivalence of ESP Unitary States and Pure \|Sz=0rangle States -- References -- Index.
Record Nr.	UNISA-996466736603316

Autore	Bulou H (Hervé)
Pubbl/distr/stampa	Springer Nature, 2021
Descrizione fisica	1 online resource (219 pages)
Altri autori (Persone)	JolyLoic MariotJean-Michel ScheurerFabrice
Collana	Springer Proceedings in Physics
Soggetto topico	Spectrum analysis, spectrochemistry, mass spectrometry Atomic & molecular physics Optical physics Fluid mechanics Circuits & components
Soggetto non controllato	Spectroscopy and Microscopy Atomic, Molecular, Optical and Plasma Physics Optics, Lasers, Photonics, Optical Devices Condensed Matter Physics Magnetism, Magnetic Materials Semiconductors X-Ray Spectroscopy Synchrotron Techniques Laser-Matter Interaction Strongly Correlated Systems Magnetism x-ray light sources x-ray scattering spintronics Open Access Gauge invariance in spectroscopy molecular magnestism magnetic semiconductors Spectrum analysis, spectrochemistry, mass spectrometry Scientific equipment, experiments & techniques Atomic & molecular physics Optical physics Applied optics Materials / States of matter Electricity, electromagnetism & magnetism Electronic devices & materials
ISBN	3-030-64623-8
Classificazione	SCI038000SCI053000SCI074000SCI077000SCI078000TEC008090
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Intro -- Foreword -- Preface -- Teachers -- Scientific Committee -- Acknowledgements -- Contents -- Contributors -- 1 X-Ray Sources at Large-Scale Facilities -- 1.1 Introduction -- 1.2 A Brief Description of Synchrotrons -- 1.2.1 Introduction -- 1.2.2 The Lorentz Factor -- 1.2.3 Dipole Radiation and Synchrotron Radiation -- 1.2.4 Spectral Flux, Emittance, and Brilliance -- 1.2.5 The Radio-Frequency Power Supply -- 1.2.6 Radiation Equilibrium -- 1.2.7 Coherence -- 1.3 Sources of Synchrotron Radiation -- 1.3.1 Bending Magnets and Wigglers -- 1.3.2 Undulators -- 1.3.3 Polarization of Synchrotron Radiation -- 1.4 Diffraction-Limited Storage Rings -- 1.5 X-Ray Free-Electron Lasers -- 1.5.1 XFEL Architecture -- 1.5.2 The SASE Process -- 1.5.3 Concluding Remarks -- 1.6 Summary -- References -- 2 Concepts in Magnetism -- 2.1 Introduction -- 2.2 Exchange -- 2.2.1 Direct Exchange -- 2.2.2 Indirect Exchange -- 2.2.3 Superexchange -- 2.3 Consequences of the Heisenberg Exchange Interaction -- 2.3.1 Two Interacting Spin-12 Particles -- 2.3.2 A Chain of Spins -- 2.3.3 Three Spins -- 2.4 Orbitals -- 2.4.1 Transition Metal Ions -- 2.4.2 Spin-Orbit Interaction and Crystal Fields -- 2.4.3 Jahn-Teller Effect -- 2.5 Conclusion -- References -- 3 Electronic Structure Theory for X-Ray Absorption and Photoemission Spectroscopy -- 3.1 Introduction -- 3.2 Light-Matter Interaction -- 3.3 Ground State Electronic Structure Theory -- 3.3.1 Hartree-Fock Approximation -- 3.3.2 Density Functional Theory -- 3.4 Absorption Spectra in the Independent Particle Approximation -- 3.4.1 Dipole Selection Rules and Density of States -- 3.5 Absorption Spectra in Linear Response TDDFT -- 3.5.1 Time-Dependent Density Functional Theory -- 3.5.2 Linear Response Theory -- 3.5.3 Absorption Spectra -- 3.6 Photoemission Spectroscopy -- 3.6.1 Angle-Resolved Photoemission Spectroscopy. 3.7 Quasiparticle Theory -- 3.7.1 Green's Functions -- 3.7.2 GW Approximation -- 3.7.3 Bethe-Salpeter Equation -- 3.7.4 Static and Dynamical Mean-Field Theory -- 3.8 Conclusions -- References -- 4 X-ray Dichroisms in Spherical Tensor and Green's Function Formalism -- 4.1 Introduction -- 4.1.1 The X-ray Absorption Cross Section -- 4.1.2 Definition of Dichroisms -- 4.1.3 The Many-Body Problem in Spectra Calculations -- 4.1.4 Codes for Ligand-Field Multiplet Calculations -- 4.2 Spherical Tensor Expansion of the XAS Cross Section -- 4.2.1 The Case of Electric Dipole Transitions -- 4.2.2 The Case of Electric Quadrupole Transitions -- 4.2.3 Term a=0 -- 4.2.4 Term a=1 -- 4.2.5 Term a=2 -- 4.2.6 Term a=3 -- 4.2.7 Term a=4 -- 4.3 Conclusion -- References -- 5 Spintronics and Synchrotron Radiation -- 5.1 General Introduction to Spintronics: From Magnetoresistive Effects to the Physics of Spin-Transfer Phenomena -- 5.1.1 Giant Magnetoresistance: An Historical Point of View -- 5.1.2 Tunnelling Magnetoresistance -- 5.1.3 Magnetization Manipulation without Magnetic Fields -- 5.1.4 Summary -- 5.2 Examples of Synchrotron Radiation Contribution to Spintronics -- 5.2.1 Voltage Control of Magnetism -- 5.2.2 Spintronics with Pure Spin Current -- 5.2.3 Current-Induced Magnetization Dynamics -- 5.3 Conclusion -- References -- 6 p-Wave Superconductivity and d-Vector Representation -- 6.1 Introduction -- 6.2 Odd-Parity Pairing: BCS Wave Function and Order Parameter -- 6.3 Vectors and Cayley-Klein Representation -- 6.3.1 Position of the Problem -- 6.3.2 Useful Formula for Pauli Matrices -- 6.3.3 Rotation of a 3D Vector: Cayley-Klein Relation -- 6.4 d-Vector Representation -- 6.5 Behaviour under Rotations -- 6.5.1 Rotation in Spin Space -- 6.5.2 Rotation in Real Space -- 6.5.3 Change of Quantization Axis: Application to ESP States. 6.6 Some Uses of the d-Vector Representation -- 6.6.1 Amplitude of the d-Vector -- 6.6.2 Spin Direction -- 6.6.3 Non-unitary States -- 6.6.4 Orbital Moment -- 6.6.5 Excitation Energy of Quasiparticles -- 6.7 The Spin-Orbit Issue -- 6.7.1 Spin-Orbit and the Superconducting Order Parameter -- 6.7.2 Anisotropy of the Susceptibility for the Strong Spin-Orbit Case -- 6.8 d d d d-vector Representation of Some Known (or Suspected) p-Wave Superconductors -- 6.8.1 Phases of Superfluid 3He -- 6.8.2 UPt3 and Sr2RuO4 -- 6.9 Ferromagnetic Superconductors -- 6.9.1 ESP States -- 6.9.2 Symmetries -- 6.9.3 Microscopic Model -- 6.10 UTe2 -- 6.11 Proofs and Exercise Solutions -- 6.11.1 Proof of the Cayley-Klein Relation -- 6.11.2 Conservation of the Scalar Product under Rotation with the Definition (6.11) -- 6.11.3 Conservation of the Cross Product under Rotation with the Definition (6.11) -- 6.11.4 Rotation of the d d d d-Vector of a Simple ``Up-Up'' State -- 6.11.5 Equivalence of ESP Unitary States and Pure \|Sz=0rangle States -- References -- Index.
Record Nr.	UNINA-9910473457003321

Autore	Slenczka Alkwin
Pubbl/distr/stampa	Cham, : Springer International Publishing AG, 2022
Descrizione fisica	1 online resource (590 p.)
Altri autori (Persone)	ToenniesJ. Peter
Collana	Topics in Applied Physics
Soggetto topico	Nuclear physics Low temperature physics Spectrum analysis, spectrochemistry, mass spectrometry
Soggetto non controllato	Microscopic superfluidity X-ray imaging Spectroscopy of biomolecules Spectroscopic matrices Vibronic spectroscopy Rovibronic spectroscopy
ISBN	3-030-94896-X
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Record Nr.	UNISA-996475869903316

Autore	Slenczka Alkwin
Edizione	[1st ed.]
Pubbl/distr/stampa	Cham, : Springer International Publishing AG, 2022
Descrizione fisica	1 online resource (590 p.)
Altri autori (Persone)	ToenniesJ. Peter
Collana	Topics in Applied Physics
Soggetto topico	Nuclear physics Low temperature physics Spectrum analysis, spectrochemistry, mass spectrometry
Soggetto non controllato	Microscopic superfluidity X-ray imaging Spectroscopy of biomolecules Spectroscopic matrices Vibronic spectroscopy Rovibronic spectroscopy
ISBN	3-030-94896-X
Classificazione	SCI065000SCI074000SCI078000
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Intro -- Preface -- Contents -- Contributors -- 1 Helium Nanodroplets: Formation, Physical Properties and Superfluidity -- 1.1 History -- 1.1.1 History of Superfluidity in Helium -- 1.1.2 History of Helium as a Cryomatrix for Spectroscopy -- 1.2 Thermodynamic Properties of Helium -- 1.3 Formation and Characterization of Helium Nanodroplets -- 1.3.1 Production of Nanodroplets in Free Jet Expansions -- 1.3.2 The 4 Regimes of Isentropic Expansions -- 1.3.3 Droplet Sizes and Size Distributions in Regimes I, II, III, and IV -- 1.3.4 Velocities of Nanodroplets -- 1.4 Physical Properties of Nanodroplets -- 1.4.1 Total Energies -- 1.4.2 Excited State Energies -- 1.4.3 Radial Distributions -- 1.4.4 Internal Temperatures of Nanodroplets -- 1.5 Evidence for Superfluidity in Finite-Sized Helium Nanodroplets -- References -- 2 Small Helium Clusters Studied by Coulomb Explosion Imaging -- 2.1 Introduction -- 2.2 Experimental -- 2.2.1 Preparation of Small Helium Clusters -- 2.2.2 Coulomb Explosion Imaging -- 2.2.3 COLTRIMS -- 2.2.4 Structure Reconstruction from the Momentum Space -- 2.3 Helium Dimer -- 2.4 Helium Trimer -- 2.4.1 4He3: Ground State -- 2.4.2 4He3: Excited Efimov State -- 2.4.3 3He4He2 -- 2.5 Field-Induced Dynamics in the Helium Dimer -- 2.6 Conclusions -- References -- 3 Helium Droplet Mass Spectrometry -- 3.1 Foreword and Introduction -- 3.2 History of HND Mass Spectrometry -- 3.2.1 Pioneering Work by the Toennies Group (Göttingen) -- 3.2.2 Review of more recent research -- 3.2.3 Mass Spectrometry as a Complimentary Tool -- 3.3 Review of Recent Work by the Scheier Group (Innsbruck) -- 3.3.1 Classical HND MS Experiments -- 3.3.2 Multiply Charged Droplets -- 3.3.3 Pickup with Charged HNDs -- 3.4 Conclusion/Outlook -- References -- 4 Infrared Spectroscopy of Molecular Radicals and Carbenes in Helium Droplets. 4.1 Infrared Spectroscopy of Molecular Radicals and Carbenes in Helium Droplets -- 4.1.1 Experimental Methods -- 4.1.2 Infrared Spectroscopy of Hydrocarbon Radicals -- 4.1.3 Rcdot + (3Σg-)O2 Chemistry in Helium Droplets -- 4.1.4 Infrared Spectroscopy of Hydroxycarbenes -- References -- 5 Electronic Spectroscopy in Superfluid Helium Droplets -- 5.1 Introduction -- 5.2 Electronic Spectroscopy -- 5.3 Electronic Spectra of Molecules in Helium Droplets -- 5.3.1 Glyoxal in Superfluid Helium Droplets -- 5.3.2 Tetracene in Superfluid Helium Droplets -- 5.3.3 Phthalocyanine in Superfluid Helium Droplets -- 5.3.4 Porphin in Superfluid Helium Droplets -- 5.3.5 Summary -- 5.3.6 Low Energy Torsional and Bending Modes in Electronic Spectra of Molecules in Helium Droplets -- 5.4 Van Der Waals Clusters Generated in Helium Droplets -- 5.4.1 Van Der Waals Clusters of Tetracene with Argon Atoms -- 5.4.2 Van Der Waals Clusters of Anthracene with Argon Atoms -- 5.4.3 Van Der Waals Clusters of Phthalocyanine with Argon Atoms -- 5.4.4 Summary -- 5.5 Elementary Chemical Reactions in Helium Droplets -- 5.5.1 Bimolecular Reaction of Barium with Nitrous Oxide -- 5.5.2 Photolysis of Iodomethane and Perfluorated Iodomethane in Helium Droplets -- 5.5.3 Excited State Intramolecular Proton Transfer (ESIPT) in Superfluid Helium Droplets -- 5.5.4 Summary -- 5.6 Concluding Remarks on Electronic Spectroscopy of Molecules in Superfluid Helium Droplets -- References -- 6 Spectroscopy of Small and Large Biomolecular Ions in Helium-Nanodroplets -- 6.1 Introduction -- 6.1.1 Infrared Spectroscopy -- 6.1.2 Action Spectroscopy -- 6.1.3 IR Multiple Photon Dissociation (IRMPD) Action Spectroscopy -- 6.1.4 Action Spectroscopy Using Helium Nanodroplets -- 6.2 Experiments on Ions in Helium Nanodroplets -- 6.2.1 Pickup of Mass-to-Charge Selected Ions in Helium Droplets. 6.2.2 The FHI Free-Electron Laser -- 6.2.3 IR Excitation of Ions in Helium Droplets -- 6.3 Spectroscopy of Ions in Helium Droplets: Results on Small Anionic Complexes and Carbohydrates -- 6.3.1 Fluoride-CO2-H2O Chemistry -- 6.3.2 Carbohydrates -- 6.3.3 Mono- and Disaccharides -- 6.3.4 Trisaccharides -- 6.3.5 Naturally Occurring Tetrasaccharides -- 6.4 Conclusions -- References -- 7 X-Ray and XUV Imaging of Helium Nanodroplets -- 7.1 Introduction -- 7.2 Imaging -- 7.2.1 Lens-Based and Lensless Imaging -- 7.2.2 Coherent Light Sources -- 7.2.3 Coherent Diffractive Imaging -- 7.2.4 Small-Angle and Wide-Angle Scattering -- 7.3 Coherent Diffractive Imaging with Helium Droplets -- 7.3.1 Experimental Setup for X-Ray and XUV Imaging -- 7.3.2 Diffraction Imaging of Helium Nanodroplets -- 7.3.3 Dopant Clusters Image Reconstruction -- 7.3.4 Forward Simulation and Machine Learning -- 7.4 Imaging Pure Helium Droplets -- 7.4.1 Shapes of Pure Helium Droplets -- 7.4.2 Droplet Stability Curve -- 7.4.3 Non-superfluid Helium Droplets -- 7.5 Imaging Dopant Cluster Structures in a Superfluid Helium Droplet -- 7.5.1 Vortex Structures in Superfluid Helium Droplets -- 7.5.2 Vortex Lattices and Angular Momentum Determination -- 7.5.3 Controlling Structures Formed in Helium Droplets -- 7.6 Imaging Dynamical Processes in Helium Droplets -- 7.7 Summary and Outlook -- References -- 8 Electron Diffraction of Molecules and Clusters in Superfluid Helium Droplets -- 8.1 Introduction -- 8.2 Theory -- 8.2.1 Theoretical Concept of Gas-Phase Electron Diffraction -- 8.2.2 Implementation and Challenges -- 8.3 Experiment -- 8.4 Characterization of Droplet Sizes -- 8.5 Image and Data Processing -- 8.6 Case Study -- 8.6.1 Electron Diffraction of Pure Droplets at Different Temperatures -- 8.6.2 Single Dopant Case: Ferrocene -- 8.6.3 Small Cluster of the Simple Molecules: CBr4. 8.6.4 Halogen Bond Case in the Case of I2 -- 8.6.5 CS2 -- 8.6.6 Diffraction of Molecules Only with Light Atoms: Pyrene -- 8.7 Conclusion -- References -- 9 Laser-Induced Alignment of Molecules in Helium Nanodroplets -- 9.1 Introduction -- 9.2 Alignment of Isolated Molecules -- 9.2.1 Laser-Induced Alignment: Basics -- 9.2.2 Nonadiabatic and Adiabatic Alignment: OCS Example -- 9.2.3 Experimental Setup -- 9.2.4 Experimental Observations of Adiabatic Alignment -- 9.2.5 Experimental Observations of Nonadiabatic Alignment -- 9.2.6 Laser-Induced Alignment: A Versatile and Useful Technique -- 9.3 Alignment of Molecules in Helium Nanodroplets -- 9.3.1 Alignment of Molecules in a Dissipative Environment? -- 9.3.2 Alignment of Molecules in He Droplets: First Experiments -- 9.3.3 Nonadiabatic Alignment in the Weak-Field Limit: Free Rotation (Reconciling the Time and the Frequency Domains) -- 9.3.4 Nonadiabatic Alignment in the Strong-Field Limit: Breaking Free -- 9.3.5 Adiabatic Alignment of Molecules in He Nanodroplets -- 9.3.6 Long-Lasting Field-Free Alignment of Molecules -- 9.3.7 Structure Determination of Dimers in He Nanodroplets -- 9.4 Conclusion -- References -- 10 Ultrafast Dynamics in Helium Droplets -- 10.1 Introduction -- 10.2 Time-Resolved Techniques Applied to Helium Nanodroplets -- 10.2.1 Time-Resolved Photon Detection -- 10.2.2 Pump-Probe Fluorescence Detection -- 10.2.3 Time-Resolved Spectroscopy by Photoion Detection -- 10.2.4 Time-Resolved Photoelectron Spectroscopy -- 10.2.5 Time-Resolved Correlation Spectroscopy -- 10.2.6 Time-Dependent Density-Functional Theory Simulations -- 10.3 Dynamics of Atomic Dopants -- 10.3.1 Surface-Located Atoms -- 10.3.2 Solvated Atoms-Solvation Dynamics -- 10.3.3 Dynamics of Superfluid Droplets Compared to Normalfluid 3He Droplets -- 10.4 Vibrational Dynamics of Molecular Dopants. 10.4.1 Vibrational Wavepackets in Alkali Dimers and Trimers -- 10.4.2 Vibrational Wave Packets in Solvated Dimers -- 10.5 Dynamics of Highly Excited Helium Droplets -- 10.5.1 Time-Resolved XUV Spectroscopy of Pure He Nanodroplets -- 10.5.2 Interatomic Coulombic Decay Processes in Doped Helium Nanodroplets -- 10.5.3 Dynamics of Helium Nanoplasmas -- 10.6 Coherent Multidimensional Spectroscopy in Helium Nanodroplets -- 10.6.1 Spectroscopic Concepts of Wave Packet Interferometry and Coherent Multidimensional Spectroscopy -- 10.6.2 Resolving the Experimental Challenges -- 10.6.3 High Resolution Wave Packet Interferometry -- 10.6.4 Ultrafast Droplet-Induced Coherence Decay in Alkali Dopants -- 10.6.5 Coherent Multidimensional Spectroscopy of Doped Helium Nanodroplets -- 10.7 Conclusions and Outlook -- References -- 11 Synthesis of Metallic Nanoparticles in Helium Droplets -- 11.1 Introduction -- 11.2 Nanoparticle Synthesis with Helium Droplets -- 11.2.1 Doping of Helium Nanodroplets -- 11.2.2 Aggregation of Nanoparticles -- 11.2.3 Nanoparticle Growth -- 11.2.4 Core@shell Nanoparticles -- 11.2.5 Deposition of Nanoparticles -- 11.2.6 Size and Shape of Nanoparticles Synthesized with Helium Droplets -- 11.3 Metal Nanoparticles -- 11.3.1 Thermal Stability of Metal Particles and Nanoscale Alloying Processes -- 11.3.2 Plasmonic Metals in Helium Droplets -- 11.3.3 Metal Nanoparticles and Molecules -- 11.3.4 Beyond Two-Component Core@shell Nanoparticles -- 11.4 Metal Oxide Nanoparticles -- 11.4.1 Determination of Oxidation States -- 11.4.2 Oxidation Experiments with Deposited Metal Nanoparticles -- 11.4.3 Metal Core-Transition Metal Oxide Shell Nanoparticles -- 11.5 Outlook -- References -- Appendix Helium Cluster and Droplet Spectroscopy Reviews -- Index.
Record Nr.	UNINA-9910571782803321