Global ETD Search

11	Improved Trial Wave Functions for Quantum Monte Carlo Calculations of Nuclear Systems and Their Applications January 2019 (has links) abstract: Quantum Monte Carlo is one of the most accurate ab initio methods used to study nuclear physics. The accuracy and efficiency depend heavily on the trial wave function, especially in Auxiliary Field Diffusion Monte Carlo (AFDMC), where a simplified wave function is often used to allow calculations of larger systems. The simple wave functions used with AFDMC contain short range correlations that come from an expansion of the full correlations truncated to linear order. I have extended that expansion to quadratic order in the pair correlations. I have investigated this expansion by keeping the full set of quadratic correlations as well an expansion that keeps only independent pair quadratic correlations. To test these new wave functions I have calculated ground state energies of 4He, 16O, 40Ca and symmetric nuclear matter at saturation density ρ = 0.16 fm−3 with 28 particles in a periodic box. The ground state energies calculated with both wave functions decrease with respect to the simpler wave function with linear correlations only for all systems except 4He for both variational and AFDMC calculations. It was not expected that the ground state energy of 4He would decrease due to the simplicity of the alpha particle wave function. These correlations have also been applied to study alpha particle formation in neutron rich matter, with applications to neutron star crusts and neutron rich nuclei. I have been able to show that this method can be used to study small clusters as well as the effect of external nucleons on these clusters. / Dissertation/Thesis / Doctoral Dissertation Physics 2019 Physics Light Clustering Nuclear Physics Quantum Monte Carlo Short Range Correlations Trial Wave Function
12	The Schrodinger Equation of a Particle in a Time Dependent Electric Field: Case Studies Smith, John Matthew, Smith 11 December 2018 (has links) No description available. Mathematics Physics
13	Characterization of metallic and insulating properties of low-dimensional systems / Caractérisation des propriétés métalliques et isolantes pour des systèmes de basse dimensionalité El Khatib, Muammar 07 July 2015 (has links) Dans cette thèse nous avons étudié des indicateurs visant à caractériser les propriétés métalliques ou isolantes de systèmes de basse dimensionnalité à partir de calculs théoriques basés sur la fonction d'onde. Ces systèmes sont intéressants car ils permettent une compréhension en profondeur des phénomènes physiques qui peuvent ensuite être extrapolés à des systèmes plus étendus. Afin de réaliser cette étude nous avons utilisé un nouvel outil basé sur la théorie de la conductivité de Kohn : le tenseur de délocalisation total ou total position spread-tensor (TPS). Ce tenseur est défini comme le second cumulant de l'opérateur position : ? = <?\|X2\|?> - <?\|X\|?>2. Divisé par le numéro des électrons, il diverge quand la fonction d'onde est fortement délocalisée (forte fluctuation de la position des électrons) et converge vers une valeur finie dans le cas contraire. Ainsi, la conductivité est relié à la délocalisation de la fonction d'onde. Dans ce travail, deux définitions du TPS ont été abordées : une quantité sommée sur le spin (spin-summed TPS, SS-TPS) d'une part, et une décomposition selon le spin (spin-partitioned TPS, SSP-TSP) d'autre part. Cette dernière s'est avérée être un outil très efficace pour l'étude de systèmes fortement corrélés. Au cours de la thèse, nous avons commencé par étudier plusieurs systèmes diatomiques présentant des liaisons de natures différentes à l'aide de calculs d'interaction de configurations totale (FCI). Le TPS présente alors un maximum dans une zone précédant la rupture de liaison avant de converger asymptotiquement vers les valeurs atomiques, comme la consistance de taille du tenseur le laissait présager. Dans le cas de systèmes pour lesquels l'état électronique présente un croisement évité, le TPS diverge, mettant ainsi en évidence la forte délocalisation de la fonction d'onde. Le SS-TPS est donc un indicateur de choix pour suivre la nature de la liaison chimique. Nous avons ensuite considéré des systèmes à valence mixte de type II pour lesquels l'état fondamental présente un double-puits de potentiel avec un croisement évité avec le premier état excité. Il est donc nécessaire ici d'utiliser un traitement multi-configurationnel. Deux systèmes modèles ont ainsi été étudiés : i) deux di- mères H2 en interaction faible au niveau FCI et ii) un composé du type spiro au niveau CAS-SCF (à l'aide d'un code que nous avons implémenté dans Molpro). Dans les deux cas, le TPS présentait un maximum très marqué dans la région du croisement évité, signature d'une forte mobilité électronique. Nous nous sommes également intéressés à trois types de chaines d'atomes d'hydrogène : i atomes équidistants ii) chaines dimérisées à longueur de liaison H2 fixée et iii) chaines dimérisées. Tant le SS-TPS que le SP-TPS montrent des comportements différents selon le type de chaine considérée. Les premières ont un caractère métallique et une délocalisation de spin prononcée dans le régime fortement corrélé. Les secondes sont de nature isolante avec une délocalisation limitée. Les chaines dimérisées, quant à elle, dissocient très rapidement vers un état isolant mais avec une forte délocalisation de spin. Ces chaines demi-remplies ont aussi été traitées à l'aide d'hamiltonien de Hubbard et de Heisenberg. Nous avons ainsi pu rationaliser le comportement des SS-TPS et SP-TPS en variant le rapport de l'intégrale de saut et de la répulsion électron- électron (-t/U) entre sites adjacents. Le caractère ferromagnétique/anti-ferromagnétique a également pu être suivi en modifiant la valeur de la constante de couplage J dans le cas fortement corrélé. Finalement, ces indicateurs ont été mis en oeuvre pour des polyacenes cycliques. Dans ce cas, le TPS a permis de comprendre la nature des fonctions d'onde de l'état fondamental obtenues au niveau CAS-SCF et NEVPT2. / I carried out a theoretical study to characterize metallic and insulating properties of low-dimensional systems using wave function methods. Low-dimensional systems are particularly important because they allow an understanding that can be extrapolated to higher dimensional systems. We have employed a new tool based on the theory of conductivity of Kohn that we have named: total position-spread tensor (TPS). The TPS is defined as the second moment cumulant of the total position operator: ? = <?\|X2\|?> - <?\|X\|?>2 . The tensor divided by the number of electrons diverges when the wave function is delocalized (high fluctuation of electrons' positions), and it takes finite values for localized ones. In this way, the electrical conductivity is related to the proper delocalization of the wave function. In addition, the tensor can be divided in spin-summed (SS-TPS) and spin-partitioned tensors (SP-TPS). The latter one becomes a powerful tool to the study of strongly correlated systems. In this dissertation, we started to investigate at full configuration interaction (FCI) level diatomic molecules showing different types of bond. The TPS presented a marked maximum before the bond was broken and in the asymptotic limit one recovers the TPS values of isolated atoms (size consistency). For the case of diatomic systems showing avoided-crossing electronic states, the TPS diverges evidencing the high delocalization of the wave function. Therefore, the SS-TPS is capable of monitoring and characterizing molecular wave functions. We considered mixed-valence systems that are often distinguished by a double-well potential energy surface presenting an avoided-crossing. Thus, such a configuration possesses a strongly multireference nature involving at least two states of the same symmetry. Two different systems were investigated: i) two weakly interacting hydrogen dimers that were investigated at Full CI level, and ii) a spiro like molecule where the TPS tensor was evaluated in a CAS-SCF state-averaged wave function using our implementation of the SS- TPS formalism in MOLPRO. We found that the tensor's component in the direction of the electron transfer (ET) shows a marked maximum in the avoided-crossing region, evidencing the presence of a high electron mobility. The formalisms of the SS- and SP-TPS was applied to one dimensional systems composed by three types of half-filled hydrogen chains: i) equally-spaced chains, ii) fixed-bond dimerized chains, and iii) homothetic dimerized chains. Both the SS- and SP-TPS showed different signatures associated to the three types of systems. Equally-spaced chains have metallic wave functions and a high spin delocalization in the strongly correlated regime. In contrast, fixed-bond dimerized chains have an insulating character and a restricted spin delocalization. Finally, homothetic dimerized chains dissociate very quickly which renders them in the insulating state but with a high spin delocalization. We also studied half-filled chains by using the Hubbard and the Heisenberg Hamiltonians. On the one hand, we were able to depict the response of the SS- and SP-TPS by varying the ratio between the hopping and electron-electron repulsion (-t/U parameter) of topological connected sites. On the other hand, the ferromagnetic and anti-ferromagnetic character of the wave functions were evaluated by varying the coupling constant (J) in the strongly correlated systems. A theoretical study of closed polyacenes (PAH) structures was performed at CAS-SCF and NEVPT2 level. Our methodology for choosing the active space using the Hückel Hamiltonian was able to characterize the ground state of the systems that indeed fulfilled the Ovchinnikov rule. Finally, we applied the SS-TPS to understand the nature of the wave functions of these PAHs. Metals Kohn localization Insulators Electron delocalization Wave function Low-dimensional systems Total position-spread tensor Metal-insulator transitions Metals Insulators Wave function Total position-spread tensor Kohn localization Electron delocalization Low-dimensional systems Metal-insulator transitions
14	Theoretical Actinide Chemistry – Methods and Models Wåhlin, Pernilla January 2011 (has links) The chemistry of actinides in aqueous solution is important, and it is essential to build adequate conceptual models and develop methods applicable for actinide systems. The complex electronic structure makes benchmarking necessary. In the thesis a prototype reaction of the water exchange reaction for uranyl(VI), for both ground and luminescent states, described with a six-water model, was used to study the applicability of density functional methods on actinides and different solvation models. An excellent agreement between the wave function methods CCSD(T) and MP2 was obtained in the ground state, implying that near-minimal CASPT2 can be used with conﬁdence for the reaction in the luminescent state of uranyl(VI), while density functionals are not suited to describe energetics for this type of reaction. There was an ambiguity concerning the position of the waters in the second hydration sphere. This issue was resolved by investigating a larger model, and prop- erly used the six-water model was found to adequately describe the water exchange reaction. The effect of solvation was investigated by comparing the results from conductor-like polarizable continuum models using two cavity models. Scattered numbers made it difficult to determine which solvation model to use. The ﬁnal conclusion was that the water exchange reaction in the luminescent state of uranyl(VI) should be addressed with near-minimal CASPT2 and a solvation model without explicit cavities for hydrogens. Finally it was shown that no new chemistry appears in the luminescent state for this reaction. The thesis includes a methodological investigation of a multi-reference density functional method based on a range separation of the two-electron interaction. The method depends on a universal parameter, which has been determined for lighter elements. It is shown here that the same parameter could be used for actinides, a prerequisite for further development of the method. The results are in that sense promising. Actinide Quantum chemistry Wave function Density functional theory Solvent models Water exchange Molecular configurations
15	Condensação Bose-Einstein em sistemas de átomos de 4He / Bose-Einstein condensation in systems of 4He atoms Pedroso, Vitor Zamprônio, 1990- 12 September 2014 (has links) Orientador: Silvio Antonio Sachetto Vitiello / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-26T08:38:32Z (GMT). No. of bitstreams: 1 Pedroso_VitorZampronio_M.pdf: 1351334 bytes, checksum: 9c35568e525b0eca7e7eb168eb22baa4 (MD5) Previous issue date: 2014 / Resumo: Neste trabalho estudamos a condensação Bose-Einstein em sistemas formados por átomos de 4He. Para tanto, introduzimos uma nova função de onda sombra que permite o cálculo da fração de condensado do sistema a T = 0 K diretamente das configurações geradas no cálculo da energia variacional. A função proposta é construída através da integração sobre um conjunto de variáveis auxiliares que interagem com todos os átomos do sistema. Esta função é translacionalmente invariante mesmo na fase sólida e satisfaz a estatística de Bose-Einstein. Utilizando essa nova função de onda concluímos que aproximadamente 4% dos átomos estão no estado de menor energia e o sistema apresenta ordem de longo alcance fora da diagonal. Resultados de energia variacional e função de distribuição radial de pares também são apresentados. As integrais de configuração espaciais foram realizadas utilizando o método de Monte Carlo / Abstract: We study the Bose-Einstein condensation in systems formed by 4He atoms. To this end, we introduce a new shadow wave function that enables the calculation of the condensate fraction of the system at T = 0 K directly from the configurations generated in the calculation of the variational energy. The proposed function is constructed by an integration over a set of auxiliary variables that interact with all the atoms of the system. This function is translationally invariant even in the solid phase and satisfies the Bose- Einstein statistics. Using this new wave function we conclude that approximately 4% of the atoms are in the lowest energy state and the system displays off-diagonal long ranged order. Results from variational energy and pair distribution function are also presented. The configuration integrations were performed using the Monte Carlo method / Mestrado / Física / Mestre em Física Bose-Einstein, Condensação de Monte Carlo, Método de Função de onda sombra Bose-Einstein condensation Monte Carlo method Shadow wave function
16	Técnicas optimizadas de análisis de señal en dominio tiempo-frecuencia para el diagnóstico de máquinas de inducción en régimen transitorio Cortés López, José Miguel 21 March 2016 (has links) [EN] After making a review of the state of the art, present laboratory equipment, types of trials and signs that have been used to experimentally validate diagnostic techniques proposed in this paper as well as justify drawbacks or limitations transform short time Fourier (STFT) with classic windows for analyzing transient signals whith diagnostic finnish rotating electrical machines in the field, selecting the prolate spheroidal function is proposed, assessing the effect of the parameters that for your definition, as optimal window for time-frequency analysis of the stator current using said transformed, so it makes a proposal to reduce the computation time and memory capacity calculation of this analysis of this signal by moving the window in the domain frequency rather than the temporary. Thus it contributes to the reduction in terms of processing times and memory requirements without losing quality when it comes to the information about the failure is both essential factors for achieving the goal that solutions for its implementation in real industrial environments with limited memory or communication if it is isolated or remote systems. / [ES] Tras hacer una revisión del estado del arte, presentar el equipamiento de laboratorio, los tipos de ensayos y señales que se han empleado para validar experimentalmente las técnicas de diagnosis propuestas en este trabajo, así como justifi car los inconvenientes o limitaciones de la transformada short time Fourier (STFT) con las ventanas clásicas para el análisis de señales en régimen transitorio con fi nes de diagnóstico en máquinas eléctricas rotativas en campo, se propone la selección de la función prolate esferoidal, valorando el efecto de los parámetros que la defi nen, como ventana óptima para el análisis tiempo-frecuencia de la corriente estatórica empleando dicha transformada, así mismo se formula una propuesta para reducir el tiempo de cómputo y la capacidad de memoria de cálculo de este análisis de esta señal moviendo la ventana en el dominio de la frecuencia en lugar del temporal. De esta forma se contribuye a la reducción en cuanto a tiempos de procesado y a los requisitos de memoria necesarios sin perder calidad en lo que a la información referente al fallo se trata, ambos factores esenciales para alcanzar la meta de que las soluciones permitan su implementación en entornos industriales reales, con limitaciones de memoria o comunicación si se trata de sistemas aislados o remotos. / [CAT] Després de fer una revisió de l'estat de l'art, presentar l'equipament de laboratori, els tipus d'assajos i senyals que s'han empleat per a validar experimentalment les tècniques de diagnosis proposades en este treball, així com justi car els inconvenients o limitacions de la transformada short time Fourier transform (STFT) amb les finestres clàssiques per a l'anàlisi de senyals en règim transitori amb fi ns de diagnòstic en Màquines elèctriques rotatives en camp, es proposa la selecció de la funció prolate esferoïdal, valorant l'efecte dels paràmetres que la de finixen, com a fi nestra òptima per a l'anàlisi temps-freqüència del corrent estatórica emprant dita transformada, així mateix es formula una proposta per a reduir el temps de còmput i la capacitat de memòria de càlcul d'esta anàlisi d'este senyal movent la finestra en el domini de la freqüència en lloc del temporal. D'esta manera es contribuïx a la reducció quant a temps de processat i als requisits de memòria necessaris sense perdre qualitat en el que a la informació referent a la fallada es tracta, ambdós factors essencials per a aconseguir la meta que les solucions permeten la seua implementació en entorns industrials reals, amb limitacions de memòria o comunicació si es tracta de sistemes aïllats o remots. / Cortés López, JM. (2016). Técnicas optimizadas de análisis de señal en dominio tiempo-frecuencia para el diagnóstico de máquinas de inducción en régimen transitorio [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/61976 / TESIS Máquinas eléctricas rotativas Diagnóstico de fallos Mantenimiento por condición Prolate spheroidal wave function INGENIERIA ELECTRICA
17	Studies on Electron Dynamics in Deformed Graphene Zhai, Dawei January 2018 (has links) No description available. Physics Condensed Matter Physics Theoretical Physics Materials Science Graphene spinor wave function quantum Hall effect pseudo-spin polarization
18	O uso do método da coordenada geradora na teoria do funcional da densidade / The generator coordinate method in density-functional theory Orestes, Ednilson 19 October 2007 (has links) Esta tese apresenta uma nova aproximação variacional baseada no Método da Coordenada Geradora e na Teoria do Funcional da Densidade. Nesta nova aproximação, a função de onda de muitos corpos é representada como uma superposição de determinantes de Slater Kohn-Sham não-ortogonais calculados a partir de Hamiltonianos diferentes que carregam uma coordenada geradora atuando como parâmetro de deformação. A discretização integral sobre o conjunto de coordenadas geradoras fornece a energia total variacional do sistema e a contribuição de cada determinante na combinação da respectiva função de onda de muitos corpos. A flexibilidade desta nova metodologia permitiu aplicá-la no estudo das energias totais do estado fundamental e excitado dos átomos da série isoeletrônica do Hélio, utilizando diferentes conjuntos de coordenadas geradoras, diferentes aproximações para o potencial de troca e correlação e diferentes maneiras de implementar a coordenada geradora dentro do Hamiltoniano Kohn-Sham. Em seguida, as bases desta nova metodologia foram estendidas para o caso dependente do tempo, permitindo estudar, por exemplo, processos não-lineares como excitações duplas, conhecidas por sua forte dependência dos efeitos de memória. A nova metodologia foi aplicada no estudo das oscilações paramétricas de um sistema de dois elétron sob um potencial harmônico, o átomo de Hooke. Os resultados demonstram que a escolha adequada das coordenadas geradoras reproduz com precisão os efeitos lineares e não-lineares dos elétrons do sistema que não podem ser descritos pela Teoria do Funcional da Densidade Dependente do Tempo utilizando a aproximação adiabática. Assim, a nova metodologia mostra-se: flexível, pois permite calcular propriedades do estado fundamental e excitado, estáticas e dinâmicas dos sistemas eletrônicos fornecendo ainda uma aproximação variacional para as respectivas funções de onda de muitos corpos em todos os casos; e também viável, pois fornece resultados promissores no caso independente do tempo constituindo uma ferramenta simples e computacionalmente barata de incluir os efeitos de memória em qualquer aproximação adiabática no caso dependente do tempo. / A new variational approach based on the Generator Coordinate Method and Density- Functional Theory is presented. It represents the interacting many-body wave function as a superposition of non-orthogonal Kohn-Sham Slater determinants arising from different Hamiltonians featuring a generator coordinate acting as a deformation parameter. An integral discretization procedure over the set of generator coordinates provides the variational total energy of the system and the weight of each determinant in the approximation of the respective interacting many-body wave functions. The method was used to calculate the ground and excited state total energies of the Helium isoelectronic serie of atoms using different sets of generator coordinates, different approximations to the exchange-correlation potential and different implementations of the generator coordinate whithin the Kohn-Sham Hamiltonian. Next, the time dependent extension of the method is presented allowing its application, for example, on the study of nonlinear processess as double excitations which are known to be strongly dependent of the memory effects. As an illustration, the method is sucessfully applied to driven parametric oscillations of a two interacting electrons in a harmonic potential, the Hooke\'s atom. It is demonstrated that a proper choice of time-dependent generator coordinates in conjunction with the adiabatic local-density approximation reproduces the exact linear and nonlinear twoelectron dynamics quite accurately, including features associated with double excitations that cannot be captured by Time-Dependent Density-Functional Theory in the adiabatic approximation. Therefore, the method is considered, flexible since it allows to calculate ground and excited-states, static and dynamic properties of the electronic systems yeilding a variational approach to the interacting many-body wave functions for all cases, and feasible, since it improves the results for ground and excited-states total energies in the time-independente case, besides to be a conceptually and computationally simple tool to build memory effects into any existing adiabatic exchange-correlation potential in the time-dependent case. campos fortes coordenada geradora density-functional efeitos de memória estados excitados excited-states função de onda de muitos corpos funcional da densidade generator coordinate many-body wave function memory effects strong fields
19	Backflow and pairing wave function for quantum Monte Carlo methods López Ríos, Pablo January 2016 (has links) Quantum Monte Carlo (QMC) methods are a class of stochastic techniques that can be used to compute the properties of electronic systems accurately from first principles. This thesis is mainly concerned with the development of trial wave functions for QMC. An extension of the backflow transformation to inhomogeneous electronic systems is presented and applied to atoms, molecules and extended systems. The backflow transformation I have developed typically retrieves an additional 50% of the remaining correlation energy at the variational Monte Carlo level, and 30% at the diffusion Monte Carlo level; the number of parameters required to achieve a given fraction of the correlation energy does not appear to increase with system size. The expense incurred by the use of backflow transformations is investigated, and it is found to scale favourably with system size. Additionally, I propose a single wave function form for studying the electron-hole system which includes pairing effects and is capable of describing all of the relevant phases of this system. The effectiveness of this general wave function is demonstrated by applying it to a particular transition between two phases of the symmetric electron-hole bilayer, and it is found that using a single wave function form gives a more accurate physical description of the system than using a different wave function to describe each phase. Both of these developments are new, and they provide a powerful set of tools for designing accurate wave functions. Backflow transformations are particularly important for systems with repulsive interactions, while pairing wave functions are important for attractive interactions. It is possible to combine backflow and pairing to further increase the accuracy of the wave function. The wave function technology that I have developed should therefore be useful across a very wide range of problems. 530
20	O uso do método da coordenada geradora na teoria do funcional da densidade / The generator coordinate method in density-functional theory Ednilson Orestes 19 October 2007 (has links) Esta tese apresenta uma nova aproximação variacional baseada no Método da Coordenada Geradora e na Teoria do Funcional da Densidade. Nesta nova aproximação, a função de onda de muitos corpos é representada como uma superposição de determinantes de Slater Kohn-Sham não-ortogonais calculados a partir de Hamiltonianos diferentes que carregam uma coordenada geradora atuando como parâmetro de deformação. A discretização integral sobre o conjunto de coordenadas geradoras fornece a energia total variacional do sistema e a contribuição de cada determinante na combinação da respectiva função de onda de muitos corpos. A flexibilidade desta nova metodologia permitiu aplicá-la no estudo das energias totais do estado fundamental e excitado dos átomos da série isoeletrônica do Hélio, utilizando diferentes conjuntos de coordenadas geradoras, diferentes aproximações para o potencial de troca e correlação e diferentes maneiras de implementar a coordenada geradora dentro do Hamiltoniano Kohn-Sham. Em seguida, as bases desta nova metodologia foram estendidas para o caso dependente do tempo, permitindo estudar, por exemplo, processos não-lineares como excitações duplas, conhecidas por sua forte dependência dos efeitos de memória. A nova metodologia foi aplicada no estudo das oscilações paramétricas de um sistema de dois elétron sob um potencial harmônico, o átomo de Hooke. Os resultados demonstram que a escolha adequada das coordenadas geradoras reproduz com precisão os efeitos lineares e não-lineares dos elétrons do sistema que não podem ser descritos pela Teoria do Funcional da Densidade Dependente do Tempo utilizando a aproximação adiabática. Assim, a nova metodologia mostra-se: flexível, pois permite calcular propriedades do estado fundamental e excitado, estáticas e dinâmicas dos sistemas eletrônicos fornecendo ainda uma aproximação variacional para as respectivas funções de onda de muitos corpos em todos os casos; e também viável, pois fornece resultados promissores no caso independente do tempo constituindo uma ferramenta simples e computacionalmente barata de incluir os efeitos de memória em qualquer aproximação adiabática no caso dependente do tempo. / A new variational approach based on the Generator Coordinate Method and Density- Functional Theory is presented. It represents the interacting many-body wave function as a superposition of non-orthogonal Kohn-Sham Slater determinants arising from different Hamiltonians featuring a generator coordinate acting as a deformation parameter. An integral discretization procedure over the set of generator coordinates provides the variational total energy of the system and the weight of each determinant in the approximation of the respective interacting many-body wave functions. The method was used to calculate the ground and excited state total energies of the Helium isoelectronic serie of atoms using different sets of generator coordinates, different approximations to the exchange-correlation potential and different implementations of the generator coordinate whithin the Kohn-Sham Hamiltonian. Next, the time dependent extension of the method is presented allowing its application, for example, on the study of nonlinear processess as double excitations which are known to be strongly dependent of the memory effects. As an illustration, the method is sucessfully applied to driven parametric oscillations of a two interacting electrons in a harmonic potential, the Hooke\'s atom. It is demonstrated that a proper choice of time-dependent generator coordinates in conjunction with the adiabatic local-density approximation reproduces the exact linear and nonlinear twoelectron dynamics quite accurately, including features associated with double excitations that cannot be captured by Time-Dependent Density-Functional Theory in the adiabatic approximation. Therefore, the method is considered, flexible since it allows to calculate ground and excited-states, static and dynamic properties of the electronic systems yeilding a variational approach to the interacting many-body wave functions for all cases, and feasible, since it improves the results for ground and excited-states total energies in the time-independente case, besides to be a conceptually and computationally simple tool to build memory effects into any existing adiabatic exchange-correlation potential in the time-dependent case. campos fortes coordenada geradora efeitos de memória estados excitados função de onda de muitos corpos funcional da densidade density-functional excited-states generator coordinate many-body wave function memory effects strong fields

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