Global ETD Search

131	Multi-Electron Coincidence Studies of Atoms and Molecules Andersson, Egil January 2010 (has links) This thesis concerns multi-ionization coincidence measurements of atoms and small molecules using a magnetic bottle time-of-flight (TOF) spectrometer designed for multi-electron coincidence studies. Also, a time-of-flight mass spectrometer has been used together with the TOF electron spectrometer for electron-ion coincidence measurements. The multi-ionization processes have been studied by employing a pulsed discharge lamp in the vacuum ultraviolet spectral region and synchrotron radiation in the soft X-ray region. The designs of the spectrometers are described in some detail, and several timing schemes suitable for the light sources mentioned above are presented. Studies have been performed on krypton, molecular oxygen, carbon disulfide and a series of alcohol molecules. For the latter, double ionization spectra have been recorded and new information has been obtained on the dicationic states. A recently found rule-of-thumb and quantum chemical calculations have been used to quantify the effective distance of the two vacancies in the dications of these molecules. For Kr, O2, and CS2, single-photon core-valence spectra have been obtained at the synchrotron radiation facility BESSY II in Berlin and interpreted on the basis of quantum chemical calculations. These spectra show a remarkable similarity to conventional valence photoelectron spectra. Spectra of triply charged ions were recorded, also at BESSY II, for Kr and CS2 by measuring, in coincidence, all three electrons ejected. The complex transition channels leading to tricationic states were mapped in substantial detail for Kr. It was found that for 3d-ionized krypton, the tricationic states are dominantly populated by cascade Auger decays via distinct intermediate states whose energies have been determined. The triple ionization spectra of CS2 from the direct double Auger effect via S2p, S2s and C1s hole states contain several resolved features and show selectivity based on the initial charge localisation and on the identity of the initial state. multi-ionization electron emission time-of-flight spectroscopy coincidence spectroscopy core-valence ionization synchrotron radiation electron correlation Atomic and molecular physics Atom- och molekylfysik
132	Ultracold Rydberg Atoms in Structured and Disordered Environments Liu, Ivan Chen-Hsiu 14 January 2009 (has links) (PDF) The properties of a Rydberg atom immersed in an ultracold environment were investigated. Two scenarios were considered, one of which involves the neighbouring ground-state atoms arranged in a spatially structured configuration, while the other involves them distributed randomly in space. To calculate the influence of the multiple ground-state atoms on the Rydberg atom, Fermi-pseudopotential was used, which simplified greatly the numerical effort. In many cases, the few-body interaction can be written down analytically which reveals the symmetry properties of the system. In the structured case, we report the first prediction of the formation of ``Rydberg Borromean trimers''. The few-body interactions and the dynamics of the linear A-B-A trimer, where A is the ground-state atom and B is the Rydberg atom, were investigated in the framework of normal mode analysis. This exotic ultralong-range triatomic bound state exists despite that the Rydberg-ground-state interaction is repulsive. Their lifetimes were estimated using both quantum scattering calculations and semi-classical approximations which are found to be typically sub-microseconds. In the disordered case, the Rydberg-excitation spectra of a frozen-gas were simulated, where the nuclear degrees of freedom can be ignored. The systematic change of the spectral shape with respect to the density of the gas and the excitation of the Rydberg atom were found and studied. Some parts of the spectral shape can be described by simple scaling laws with exponents given by the basic properties of the atomic species such as the polarizability and the zero-energy electron-atom scattering length. Rydberg atom ultracold physics atomic and molecular physics trilobite molecule borromean molecule Rydberg atom ultrakalt Physik Atom und Molekular Physik trilobite moleküle ddc:530 rvk:UM 2160
133	Dynamique quantique de systèmes atomiques et moléculaires dans des agrégats de gaz rares Unn-Toc, Wesley 23 July 2012 (has links) (PDF) Cette thèse présente le développement de méthodes de simulations numériques basées sur la méthode Multi-Configuration Time Dependent Hartree (MCTDH), pour la modélisation de la dynamique quantique d'espèces atomiques et moléculaires dans des agrégats de gaz rares. Nous avons étudié en particulier les effets quantiques dans la dissociation et la section efficace de capture d'agrégats de néon. Nous avons montré que le temps de vie avant dissociation est 1 à 2 ordres de grandeur plus élevé que dans le cas d'une dynamique classique. De plus, la section efficace de capture est légèrement supérieure et moins sensible à l'augmentation de l'énergie interne de l'agrégat dans le cadre de simulations quantiques que classiques. Par ailleurs, nous avons étudié la réponse d'une matrice de néon à la photo-excitation électronique d'une molécule de monoxyde d'azote avec une méthode MCTDH à dimensionalité réduite et une méthode de champ moyen à dimensionalité complète (G-TDH). Ces 2 méthodes sont systématiquement comparées par le biais de différentes observables pour évaluer la validité de la dernière méthode en vue de l'étendre aux cas où une réduction dimensionalité s'avère difficile et des calculs MCTDH sont hors de portée. Dynamique quantique MCTDH Paquets d'onde gaussiens Agrégats Nucléation
134	Time-dependent density functional theory applied to clusters and molecules in contact with an environment Dinh, Phuong Mai 07 December 2009 (has links) (PDF) We present recent theoretical and methodological explorations on the dynamics of sodium clusters in the framework of Time-Dependent Density Functional Theory (TDDFT), coupled non-adiabatically to Molecular-Dynamics (MD). In particular, a hierarchical approach, in the spirit of Quantum-Mechanical/Molecular-Mechanical methods, has been developed for the description of metal clusters in interaction with a dynamically polarizable substrate, as rare gases or MgO. Numerous examples of application of this approach (Na clusters in or on Ar substrate, Na clusters deposited on MgO; optical response, dynamical deposition, laser irradiation, ...) are reviewed. We also briefly discuss complementing research activities. Formal developments on the Self-Interaction Correction issue in DFT and TDDFT are discussed in a word. We have furthermore extended our TDDFT-MD theory to the case of organic (C, N, O, H made) systems and a few examples of investigated dynamical processes are presented. Recent calculations of photoelectron angular distributions of free metal clusters are reported as well. We finally sketch with some perspectives for the years to come. TDDFT molecular dynamics clusters environment electronic excitation electronic emission
135	SPINTRONICS IN CLUSTER-ASSEMBLED NANOSTRUCTURES Oyarzún, Simón 15 October 2013 (has links) (PDF) In the last years, the progressive miniaturization of magnetic storage devices has imposed the necessity to understand how the physical properties are modi- ed with respect to the bulk when the dimensions are reduced at the nanometric scale. For this reason an accurate method of preparation and characterization of nanostructures is extremely important. This work focuses on the magnetic and transport properties of cluster-assembled nanostructures, namely cobalt nanoparticles embedded in copper matrices. Our setup allows us to independently control the mean cluster size, the concentration and the chemical composition. The cobalt cluster production is based on magnetron sputtering and gas phase aggregation. The performance of the source permits a wide range of cluster masses, from one to several thousand atoms. As a rst step we studied the role of inter-particle interactions in the transport and magnetic properties, increasing the cobalt nanoparticle concentration (from 0.5% to 2.5% and 5%). Our results demonstrate the necessary precautions and constitute a solid basis for further studies of the spintronic properties of granular systems. Finally, in order to describe the intrinsic magnetic properties of cluster-assembled nanostructures, we prepared strongly diluted samples (<0.5%) for di erent cluster sizes from 1.9 nm to 5.5 nm. We found that the magnetic properties are size-dependent. Using a complete magnetic characterization, sensitive to the change in the e ective magnetic anisotropy, we show that the magnetic anisotropy is dominated by the contributions of the surface or of the shape of the nanoparticles. nanoparticle superparamagnetism magnetic anisotropy surface shape spintronics transport magnetoresistance concentration interactions
136	Study of the Quasielastic {sup 3}He(e,e{prime}p) Reaction at Q{sup 2}=1.5 (GeV/c){sup 2} up to Missing Momenta of 1 GeV/c Marat Rvachev January 2003 (has links) Thesis (Ph.D.); Submitted to Massachusetts Inst. of Tech., Cambridge, MA (US); 1 Sep 2003. / Published through the Information Bridge: DOE Scientific and Technical Information. "JLAB-PHY-03-167" "DOE/ER/40150-2745" Marat Rvachev. 09/01/2003. Report is also available in paper and microfiche from NTIS.
137	Ultracold Rydberg Atoms in Structured and Disordered Environments Liu, Ivan Chen-Hsiu 03 November 2008 (has links) The properties of a Rydberg atom immersed in an ultracold environment were investigated. Two scenarios were considered, one of which involves the neighbouring ground-state atoms arranged in a spatially structured configuration, while the other involves them distributed randomly in space. To calculate the influence of the multiple ground-state atoms on the Rydberg atom, Fermi-pseudopotential was used, which simplified greatly the numerical effort. In many cases, the few-body interaction can be written down analytically which reveals the symmetry properties of the system. In the structured case, we report the first prediction of the formation of ``Rydberg Borromean trimers''. The few-body interactions and the dynamics of the linear A-B-A trimer, where A is the ground-state atom and B is the Rydberg atom, were investigated in the framework of normal mode analysis. This exotic ultralong-range triatomic bound state exists despite that the Rydberg-ground-state interaction is repulsive. Their lifetimes were estimated using both quantum scattering calculations and semi-classical approximations which are found to be typically sub-microseconds. In the disordered case, the Rydberg-excitation spectra of a frozen-gas were simulated, where the nuclear degrees of freedom can be ignored. The systematic change of the spectral shape with respect to the density of the gas and the excitation of the Rydberg atom were found and studied. Some parts of the spectral shape can be described by simple scaling laws with exponents given by the basic properties of the atomic species such as the polarizability and the zero-energy electron-atom scattering length. info:eu-repo/classification/ddc/530 ddc:530
138	P-WAVE EFIMOV PHYSICS FOR THREE-BODY QUANTUM THEORY Yu-Hsin Chen (14070930) 09 November 2022 (has links) <p> </p> <p><em>P</em>-wave Efimov physics for three equal mass fermions with different symmetries has been modeled using two-body interactions of Lennard-Jones potentials between each pair of Fermi atoms, and is predicted to modify the long range three-body interaction potential energies, but without producing a real Efimov effect. Our analysis treats the following trimer angular momenta and parities, L<sup>Π</sup> = 0<sup>+</sup>,1<sup>+</sup>,1<sup>−</sup> and 2<sup>−</sup>, for either three spin-up fermions (↑↑↑), or two spin-up and one spin-down fermion (↑↓↑). Our results for the long range behavior in some of those cases agree with previous work by Werner and Castin and by Blume <em>et al.</em>, namely in cases where the s-wave scattering length goes to infinity. This thesis extends those calculated interaction energies to small and intermediate hyperradii comparable to the van der Waals length, and considers additional unitarity scenarios where the p-wave scattering volume approaches infinity. The crucial role of the diagonal hyperradial adiabatic correction term is identified and characterized. For the equal mass fermionic trimers with two different spin components near the unitary limit are shown to possess a universal van der Waals bound or resonance state near s-wave unitarity, when p-wave interactions are included between the particles with equal spin. Our treatment uses a single-channel Lennard-Jones interaction with long range two-body van der Waals potentials. While it is well-known that there is no true Efimov effect that would produce an infinite number of bound states in the unitary limit for these fermionic systems, we demonstrate that another type of universality emerges for the symmetry L<sup>Π</sup> = 1<sup>−</sup>. The universality is a remnant of Efimov physics that exists in this system at p-wave unitarity, and it leads to modified threshold and scaling laws in that limit. Application of our model to the system of three lithium atoms studied experimentally by Du, Zhang, and Thomas [Phys. Rev. Lett. <strong>102</strong>, 250402 (2009)] yields a detailed interpretation of their measured three-body recombination loss rates. </p> Atomic and molecular physics fermionic atoms Cold Atoms atomic collisions Efimov Three-body problem Three-Body Effects Three-Body Interactions P-WAVE fermion interactions
139	INTERFACE, PHASE CHANGE AND MOLECULAR TRANSPORT IN SUB, TRANS AND SUPERCRITICAL REGIMES FOR N-ALKANE/NITROGEN MIXTURES Suman Chakraborty (13184898) 01 August 2022 (has links) <p> Understanding the behavior of liquid hydrocarbon propellants under high pressure and temperature conditions is a crucial step towards improving the performance of modern-day combustion engines (liquid rocket engines, diesel engines, gas turbines and so on) and designing the next generation ones. Under such harsh thermodynamic conditions (high P&T) propellent droplets may experience anywhere from sub-to-trans-to-supercritical regime. The focus of this research is to explore the dynamics of the vapor-liquid two phase system formed by a liquid hydrocarbon fuel (n-heptane or n-dodecane) and ambient (nitrogen) over a wide range of P&T leading up to the mixture critical point and beyond. Molecular dynamics (MD) has been used as the primary tool in this research along with other tools like: phase stability calculations based on Gibb’s work, Peng Robinson equation of state, density gradient theory and neural networks.</p> Atomic and molecular physics Molecular Dynamics Phase Change Interfacial Transport Supercritical Regime Equation of state Neural Network Prediction Kinetic Boundary Condition Vapor Liquid Equilibria Mixture Critical Point
140	Etude de bruit de fond induit par les muons dans l'expérience EDELWEISS-II Chantelauze, Astrid 04 November 2009 (has links) (PDF) L'expérience EDELWEISS a pour but de détecter des WIMPs, particules massives faiblement interactives, qui pourraient composer la matière noire de l'univers. Elle mesure l'énergie libérée lors de la collision élastique d'un WIMP sur un noyau de matière ordinaire. Du fait de sa très faible section efficace d'interaction, qui conduit à un taux d'évènement extrêment bas (<1evt/kg/an) et du fait du faible dépôt d'énergie (<100keV), le signal de recul nucléaire des WIMPs peut être imité par des neutrons de la radioactivité ambiante ou induits par des muons. Cette thèse est dédiée à l'étude du bruit de fond induit par les muons. Les performances du véto muon de l'expérience EDELWEISS-II sont présentées et la détection des muons er de leurs gerbes discutés. Les premières coïncidences entre le véto muon et les bolomètres ont été réalisées sur deux prises de données de 4 mois de 2007 et 2008 et conduisent à un résultat de 0.043+-0.015 coinc/kg/j pour une énergie de recul de ER<250 keV Bruit radioélectrique Collisions (physique nucléaire)

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