999 resultados para Física de Plasmas
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Analisa com métodos cienciométricos a relação entre algumas características de uma amostra de periódicos de Física e os valores de Fator de Impacto (FI) publicados no Journal Citation Reports (JCR), no período de 1993 a 2000. As características estudadas são: sub-área do conhecimento, evolução temporal, tipo e tamanho do periódico, densidade dos artigos e ritmo de obsolescência da literatura. A amostra foi constituída de modo não aleatório, abrangendo todos os títulos classificados pelo Journal Citation Reports (JCR) como sendo de algumas sub-áreas da Física: Física; Física Aplicada; Física Atômica, Molecular e Química; Física da Matéria Condensada; Física de Fluídos e de Plasmas; Física Matemática; Física Nuclear; Física de Partículas e Campos; Ótica; e, Astronomia e Astrofísica. Ao total analisou-se 376 periódicos. Foi elaborado um banco de dados no programa Statistics Packet for Social Science (SPSS) versão 8.0 para a coleta das informações necessárias para a realização do estudo, bem como para o tratamento estatístico das mesmas. As hipóteses de trabalho foram testadas através da Análise de Variância (ANOVA), do Teste χ2 e da Dupla Análise de Variância por Posto de Friedman. As análises empreendidas resultaram na comprovação das seis hipóteses de trabalho à medida que foi verificado que as variáveis: tipo, tamanho, densidade, ritmo de obsolescência, sub-área e tempo influenciam, umas em maior grau, outras com menor intensidade, os valores de FI. Especificamente, destaca-se que o tamanho e o ritmo de obsolescência são as características dos periódicos que se correlacionam mais fortemente com o FI. A densidade apresentou o menor poder explicativo das diferenças existentes entre o impacto das publicações. O aspecto mais relevante verificado está na existência de associação entre sub-área e FI. As cinco sub-áreas que se distinguem das demais são: a Óptica e a Física Aplicada por apresentarem valores médios baixos de FI; e a Física de Partículas e Campos, a Física Atômica, Molecular e Química e a Física Nuclear devido às médias altas. O estudo conclui que o FI deve ser utilizado somente de modo contextualizado e relativizado.
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The standard kinetic theory for a nonrelativistic diluted gas is generalized in the spirit of the nonextensive statistic distribution introduced by Tsallis. The new formalism depends on an arbitrary q parameter measuring the degree of nonextensivity. In the limit q = 1, the extensive Maxwell-Boltzmann theory is recovered. Starting from a purely kinetic deduction of the velocity q-distribution function, the Boltzmann H-teorem is generalized for including the possibility of nonextensive out of equilibrium effects. Based on this investigation, it is proved that Tsallis' distribution is the necessary and sufficient condition defining a thermodynamic equilibrium state in the nonextensive context. This result follows naturally from the generalized transport equation and also from the extended H-theorem. Two physical applications of the nonextensive effects have been considered. Closed analytic expressions were obtained for the Doppler broadening of spectral lines from an excited gas, as well as, for the dispersion relations describing the eletrostatic oscillations in a diluted electronic plasma. In the later case, a comparison with the experimental results strongly suggests a Tsallis distribution with the q parameter smaller than unity. A complementary study is related to the thermodynamic behavior of a relativistic imperfect simple fluid. Using nonequilibrium thermodynamics, we show how the basic primary variables, namely: the energy momentum tensor, the particle and entropy fluxes depend on the several dissipative processes present in the fluid. The temperature variation law for this moving imperfect fluid is also obtained, and the Eckart and Landau-Lifshitz formulations are recovered as particular cases
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Mass spectrometry is a diagnosis that can aid in the understanding of the kinetics of chemical plasma environment. Through this you can get information about some species present in the environment and make inferences about the behavior of the plasma when parameters such as pressure and applied power changes. When analyzed plasmas generated by the discharge of argon and diglyme (both individually and mixtures of them in various proportions) could be found conditions in which the plasma behavior was different from what is often found in the literature. By the end some peculiar characteristics of plasmas generated by mixing argon / diglyme were raised and it was found that the noble gas is a good mediator of physical and chemical reactions that occur in the environment, and help in the understanding of chemical kinetics. Therefore mass spectrometry was shown highly important tool for the study of plasma environment
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Actually, transition from positive to negative plasma current and quasi-steady-state alternated current (AC) operation have been achieved experimentally without loss of ionization. The large transition times suggest the use of MHD equilibrium to model the intermediate magnetic field configurations for corresponding current density reversals. In the present work we show, by means of Maxwell equations, that the most robust equilibrium for any axisymmetric configuration with reversed current density requires the existence of several nonested families of magnetic surfaces inside the plasma. We also show that the currents inside the nonested families satisfy additive rules restricting the geometry and sizes of the axisymmetric magnetic islands; this is done without restricting the equilibrium through arbitrary functions. Finally, we introduce a local successive approximations method to describe the equilibrium about an arbitrary reversed current density minimum and, consequently, the transition between different nonested topologies is understood in terms of the eccentricity of the toroidal current density level sets.
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Programa de Doctorado en Física Fundamental y Aplicada
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Programa de Doctorado en Física fundamental
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Este trabajo expone el desarrollo de un método basado en algoritmos genéticos para realizar diagnosis espectroscópica de plasmas de interés en el área de la fusión nuclear por confinamiento inercial.
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Máster Universitario en Sistemas Inteligentes y Aplicaciones Numéricas en Ingeniería (SIANI)
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Programa de doctorado: Sistemas inteligentes y aplicaciones numéricas en Ingeniería
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Radiative shock waves play a pivotal role in the transport energy into the stellar medium. This fact has led to many efforts to scale the astrophysical phenomena to accessible laboratory conditions and their study has been highlighted as an area requiring further experimental investigations. Low density material with high atomic mass is suitable to achieve radiative regime, and, therefore, low density xenon gas is commonly used for the medium in which the radiative shock propagates. In this work the averageionization and the thermodynamicregimes of xenonplasmas are determined as functions of the matter density and temperature in a wide range of plasma conditions. The results obtained will be applied to characterize blastwaveslaunched in xenonclusters
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The accurate computation of radioactive opacities is needed in several research fields such as astrophysics, magnetic fusion or ICF target physics analysis, in which the radiation transport is an important feature to determine in detail. Radiation transport plays an important role in the transport of energy in dense plasma and it is strongly influenced by the variation of plasma opacity with density and temperature, as well as, photon energy. In this work we present some new features of the opacity code ATMED [1]. This code has been designed to compute the spectral radioactive opacity as well as the Rosseland and Planck means for single element and mixture plasmas. The model presented is fast, stable and reasonably accurate into its range of application and it can be a useful tool to simulate ICF experiments in plasma laboratory.
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Theoretical X-ray opacities are used in numerous radiative transfer simulations of plasmas at different temperatures and densities, for example astrophysics, fusion, metrology and EUV and X-rays radiation sources. However, there are only a reduced number of laboratories working on the validation of those theoretical results empirically, in particular for high temperature plasmas (mayor que 1eV). One of those limitations comes from the use of broad band EUV- X ray sources to illuminate the plasma which, among other issues, present low reproducibility and repetition rate [1]. Synchrotron radiation facilities are a more appropriate radiation source in that sense, since they provide tunable, reproducible and high resolution photons. Only their ?low? photon intensity for these experiments has prevented researchers to use it for this purpose. However, as new synchrotron facilities improve their photon fluxes, this limitation not longer holds [2]. This work evaluates the experimental requirements to use third generation synchrotron radiation sources for the empirical measurement of opacities of plasmas, proposing a pausible experimental set-up to carry them out. Properties of the laser or discharge generated plasmas to be studied with synchrotron radiation will be discussed in terms of their maximum temperatures, densities and temporal evolution. It will be concluded that there are encouraging reasons to pursue these kind of experiments which will provide with an appropriate benchmark for theoretical opacities
