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1	Weak Atomic Interactions Schef, Peter January 2006 (has links) <p>An atom or ion can change quantum state, usually through emission or absorption of a photon. The photon has the same energy as the energy difference between the states of the transition. The states, or energy levels, of an atom are quantized and light emitted, or absorbed, from the atom is therefore of specific wavelengths, giving spectral lines. The spectrum of an atomic ion is unique and contains information of the structure and energy levels of the ion. The spectrum of an atom can be used as a fingerprint in determinations of the abundance of the element in different objects.</p><p>This thesis is focused on some weak effects observed by spectroscopy. Although the effects are weak, they turn out to be of great importance. According to quantum mechanics transitions between certain states are not allowed. Here the weak effects open the possibility for transitions. Spectral lines from forbidden transitions are very weak and difficult to observe under ordinary laboratorial conditions, but they are commonly observed from astrophysical objects and can be very useful for diagnostics of astrophysical plasmas. The first reported observation of forbidden lines was from an astrophysical object and at that time supposed to be from new, previous unknown, elements. If all possible decay channels from an energy level are forbidden, the energy level is metastable and has usually a lifetime 10$^8$ times longer than an ordinary excited state. Measurements of such long lifetimes are difficult since the ion need to be confined during the observation time. Confinement of ions can be achieved with a storage device, such as a storage ring or a trap, where the ions are stored without interacting with each other or the surroundings.</p><p>A laser probing technique has been developed at the storage ring CRYRING, for measurements of lifetimes of metastable states. The technique has now been improved for measurement of longer lifetimes. The technique has also been modified to fit when measuring on negative ions. Results of lifetime measurements are reported and the techniques and methods used are described.</p><p>Another weak effect is hyperfine interaction, which splits the energy levels of an atom or ion. Hyperfine splitting is very small and usually special spectral techniques are needed to resolve such structure. A laser can, in combination with an electromagnetic radio-frequency field, be used for accurate determination of hyperfine structures in atomic ions. Such measurements are also important for evaluation of astrophysical properties, since hyperfine structure can broaden the spectral lines. An experimental setup for such double resonance measurements has been developed and constructed. Results of experimental measurements are reported and the technique is described.</p> metastable states forbidden transitions laser probing hyperfine structure LRDR Atomic physics Atomfysik
2	Study of semiconductor and metal surfaces using a novel scanning Kelvin probe Petermann, Uwe January 2000 (has links) No description available. 530.41
3	Weak Atomic Interactions Schef, Peter January 2006 (has links) An atom or ion can change quantum state, usually through emission or absorption of a photon. The photon has the same energy as the energy difference between the states of the transition. The states, or energy levels, of an atom are quantized and light emitted, or absorbed, from the atom is therefore of specific wavelengths, giving spectral lines. The spectrum of an atomic ion is unique and contains information of the structure and energy levels of the ion. The spectrum of an atom can be used as a fingerprint in determinations of the abundance of the element in different objects. This thesis is focused on some weak effects observed by spectroscopy. Although the effects are weak, they turn out to be of great importance. According to quantum mechanics transitions between certain states are not allowed. Here the weak effects open the possibility for transitions. Spectral lines from forbidden transitions are very weak and difficult to observe under ordinary laboratorial conditions, but they are commonly observed from astrophysical objects and can be very useful for diagnostics of astrophysical plasmas. The first reported observation of forbidden lines was from an astrophysical object and at that time supposed to be from new, previous unknown, elements. If all possible decay channels from an energy level are forbidden, the energy level is metastable and has usually a lifetime 10$^8$ times longer than an ordinary excited state. Measurements of such long lifetimes are difficult since the ion need to be confined during the observation time. Confinement of ions can be achieved with a storage device, such as a storage ring or a trap, where the ions are stored without interacting with each other or the surroundings. A laser probing technique has been developed at the storage ring CRYRING, for measurements of lifetimes of metastable states. The technique has now been improved for measurement of longer lifetimes. The technique has also been modified to fit when measuring on negative ions. Results of lifetime measurements are reported and the techniques and methods used are described. Another weak effect is hyperfine interaction, which splits the energy levels of an atom or ion. Hyperfine splitting is very small and usually special spectral techniques are needed to resolve such structure. A laser can, in combination with an electromagnetic radio-frequency field, be used for accurate determination of hyperfine structures in atomic ions. Such measurements are also important for evaluation of astrophysical properties, since hyperfine structure can broaden the spectral lines. An experimental setup for such double resonance measurements has been developed and constructed. Results of experimental measurements are reported and the technique is described. metastable states forbidden transitions laser probing hyperfine structure LRDR Atomic physics Atomfysik
4	Estudo do resfriamento em um sistema com múltiplos estados fundamentais / A study of cooling in a system with several ground states. Henrique Santos Guidi 29 October 2007 (has links) Estudamos um sistema de dois níveis acoplados como um modelo que imita o comportamento de líquidos super-resfriados. Em equilíbrio o modelo apresenta uma fase líquida e uma fase cristalina com diversos estados fundamentais. O modelo é definido numa rede quadrada e a cada sítio é associada uma variável estocástica de Ising. A característica que torna este modelo particularmente interessante é que ele apresenta estados metaestáveis duráveis que podem desaparecer dentro do tempo acessível para as simulações numéricas. Para imitar o processo de formação dos vidros, realizamos simulações de Monte Carlo a taxas de resfriamento constante. Apresentamos também simulações para resfriamentos súbitos a temperatura abaixo da temperatura de fusão. / We study a coupled two level systems as a model that imitate the behavior of supercooled liquids that become structural glasses under cooling. In the equilibrium the model shows a liquid phase and a crystalline phase with many grouond states. The model is defined on a square lattice and to each site a stochastic Ising variable is associated. The feature that makes this model particularly interesting is that it display durable metastables states which can vanish within the time available for numerical simulations. In order to imitate the glass former process, we perform Monte Carlo simulations at constant cooling rate. We present also simulations for quenchs to temperatures below the melting temperature. Algoritmo de Metropolis Estados Metaestáveis Transições de fase Vidros Glasses Metastable states. Metropolis algorithm Phase transition
5	Implantação de um espectrômetro de estados metaestáveis de alvos gasosos Alessio, Rita de Cássia Polito Vita 09 June 2009 (has links) Submitted by Renata Lopes (renatasil82@gmail.com) on 2017-06-27T18:11:39Z No. of bitstreams: 1 ritadecassiapolitovitaalessio.pdf: 1515814 bytes, checksum: ec2256bcf074df2e72a53fe6c0a62c6f (MD5) / Approved for entry into archive by Adriana Oliveira (adriana.oliveira@ufjf.edu.br) on 2017-08-07T21:06:14Z (GMT) No. of bitstreams: 1 ritadecassiapolitovitaalessio.pdf: 1515814 bytes, checksum: ec2256bcf074df2e72a53fe6c0a62c6f (MD5) / Made available in DSpace on 2017-08-07T21:06:14Z (GMT). No. of bitstreams: 1 ritadecassiapolitovitaalessio.pdf: 1515814 bytes, checksum: ec2256bcf074df2e72a53fe6c0a62c6f (MD5) Previous issue date: 2009-06-09 / CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / O estudo de ressonâncias, através de estados metaestáveis pelo impacto de elétrons, permite observar estruturas bem definidas nos espectros, gerando informações diretas sobre as energias de formação das ressonâncias, bem como suas formas e larguras. A investigação destas ressonâncias é muito importante em vários ramos da ciência, possuindo inúmeras aplicações biológicas e tecnológicas. Um espectrômetro por impacto de elétrons foi construído e implantado no Laboratório de Física Atômica e Molecular, permitindo a obtenção das funções de excitação do Argônio, do Hélio e da molécula de Nitrogênio, sendo esta técnica inédita no Brasil. Neste espectrômetro aplica-se a técnica dos feixes cruzados, que consiste basicamente de um canhão de elétrons monocromatizado, um feixe de gás efusivo, uma gaiola de Faraday para a blindagem da região de colisão, um detector de íons metaestáveis, devidamente posicionado, e um coletor de Faraday. O canhão de elétrons monocromatizado apresenta uma alta eficiência, cobrindo continuamente uma faixa de energia de 7 a 200 eV, com uma resolução em torno de 50 meV. Para a aquisição dos espectros, a energia do canhão foi varrida a partir do limiar de excitação metaestável até uma energia menor que o primeiro potencial de ionização do alvo estudado. / The study of resonances through metastable states of atoms and molecules by electron impact shows spectra with well-defined structures, providing direct information on the energies of resonances formation, as well as its shapes and widths. The investigation of these resonances is important in several branches of science, such as many technological and biological applications. In this work we have assembled at Laboratory of Atomic and Molecular Physics an electron impact spectrometer which allowed us to collect metastables excitations functions of Argon, Helium and the Nitrogen molecules. As far we know, that was the first time that this technique was performed in Brazil. That spectrometer applies the cross beam technique, and consists of a monochromatized electron gun, an effusive gas beam, a cage to shield the collision region, a metastable detector properly positioned and a Faraday cup. The monocromatized electron gun built has a high efficiency, covering continuously the energy range from 7 to 200 eV, with a resolution of about 50 meV. The three spectras recorded in this work cover the energy range from the excitation metastable threshold up to energy lower than the first ionization potential of the targets studied. CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA Ressonâncias Estados metaestáveis Impacto de elétrons Resonances Metastable states Electron impact
6	Estudo do resfriamento em um sistema com múltiplos estados fundamentais / A study of cooling in a system with several ground states. Guidi, Henrique Santos 29 October 2007 (has links) Estudamos um sistema de dois níveis acoplados como um modelo que imita o comportamento de líquidos super-resfriados. Em equilíbrio o modelo apresenta uma fase líquida e uma fase cristalina com diversos estados fundamentais. O modelo é definido numa rede quadrada e a cada sítio é associada uma variável estocástica de Ising. A característica que torna este modelo particularmente interessante é que ele apresenta estados metaestáveis duráveis que podem desaparecer dentro do tempo acessível para as simulações numéricas. Para imitar o processo de formação dos vidros, realizamos simulações de Monte Carlo a taxas de resfriamento constante. Apresentamos também simulações para resfriamentos súbitos a temperatura abaixo da temperatura de fusão. / We study a coupled two level systems as a model that imitate the behavior of supercooled liquids that become structural glasses under cooling. In the equilibrium the model shows a liquid phase and a crystalline phase with many grouond states. The model is defined on a square lattice and to each site a stochastic Ising variable is associated. The feature that makes this model particularly interesting is that it display durable metastables states which can vanish within the time available for numerical simulations. In order to imitate the glass former process, we perform Monte Carlo simulations at constant cooling rate. We present also simulations for quenchs to temperatures below the melting temperature. Algoritmo de Metropolis Estados Metaestáveis Glasses Metastable states. Metropolis algorithm Phase transition Transições de fase Vidros
7	Distribution of metastable states of spin glasses Schnabel, Stefan, Janke, Wolfhard 09 June 2023 (has links) The complex behavior of systems like spin glasses, proteins or neural networks is typically explained in terms of a rugged energy or fitness landscape. Within the high dimensional conformation space of these systems one finds features like barriers, saddle points, and metastable states whose number – at least in the case of spin glasses – grows exponentially with the size of the system. We propose a novel Monte Carlo sampling algorithm that employs an ensemble of short Markovian chains in order to visit all metastable states with equal probability. We apply this algorithm in order to measure the number of metastable states for the two dimensional and the three-dimensional Edwards-Anderson model and compare with theoretical predictions. info:eu-repo/classification/ddc/530 ddc:530
8	Development and Benchmarking of Hermitian and non-Hermitian Methods for Negative Ion Resonances Kolathingal Thodika, Mushir ul Hasan, 0000-0002-6837-9710 January 2022 (has links) Low energy electron (LEE) driven chemistry underpins a wide range of interdisciplinary fields, including radiation biology, redox chemistry, astrochemistry and biomaterial design. A growing interest in the chemistry of LEEs concerns the radiative damage to DNA. Studies have found that LEEs can induce single and double-strand breaks in DNA by forming a negative ion resonance (NIR). These processes are remarkably site-specific and have been utilized to synthesize radiosensitizers, which aid in identifying target cells in hypoxic tumors in radiation therapy. Despite the prevalence of LEE-induced reactions, computational studies of such processes are limited compared to thermal and photochemical reactions. The relative scarcity in computational studies of LEE-induced reactions stems from the difficulties in the theoretical treatment of NIRs. In our work, we report new developments on the application of quantum chemical methods to NIRs. We demonstrate that the combination of approaches developed for resonances with multi reference electronic structure methods enables the computation of various types of NIRs in a single calculation. Additionally, we show that multi-reference methods can also quantify the mixing between NIRs. It is observed that the mixing between resonances can have significant consequences on their lifetimes. We also report the development of a new technique, the continuum remover Feshbach projection operator approach, which uses the conventional methods developed for bound states to characterize resonances. We show that this new approach is straightforward to implement with standard electronic structure packages, it is efficient, and provides promising results. / Chemistry Chemistry Computational chemistry Low-energy electron Metastable states Negative ion resonances
9	SINGLE CHAIN BEHAVIOR IN METASTABLE STATES IN SEMICRYSTALLINE POLYMERS AS INVESTIGATED BY SOLID STATE NMR Yuan, Shichen 23 May 2018 (has links) No description available. Condensed Matter Physics Molecular Physics Polymers
10	An investigation of metastable electronic states in ab-initio simulations of mixed actinide ceramic oxide fuels Lord, Adam 13 November 2012 (has links) First-principles calculations such as density functional theory (DFT) employ numerical approaches to solve the Schrodinger equation of a system. Standard functionals employed to determine the cohesive system energy, specifically the local density and generalized gradient approximations (LDA and GGA), underestimate the correlation of 5f electrons to their ions in AO₂ systems (A=U/Pu/Np). The standard correction, the "Hubbard +U," causes the multidimensional energy surface to develop a large number of local minima which do not correspond to the ground state (global minimum). Because all useful energy values derived from DFT calculations depend on small differences between relatively large cohesive energies, comparing systems wherein one or more of the samples are not in the ground state has the potential to introduce large errors. This work presents an analysis of the fundamental issues of metastable states in both pure and binary AO₂ systems, investigates novel methods of handling them, and describes why current literature approaches which appear to work well for the pure compounds are not well-suited for systems containing multiple actinide species. VASP Ground state Metastable states MOX Uranium dioxide First principles Ab initio Actinide elements Radioactive wastes Multiscale modeling

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