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Émissivité de particules pour le refroidissement bremsstrahlung de supernovae par le processus de diffusion nucléon-nucléon (NN)Boulay, Jérémy 10 February 2024 (has links)
La matière sombre sert à combler la lacune de masse constatée dans la théorie de la gravité actuelle. Introduire des modèles de matière sombre comprenant des particules de type axion (une particule théorique qui semble être une solution au problème de la symétrie CP dans les interactions fortes) ou des photons sombres (une particule théorique qui pourrait résoudre le problème du moment magnétique anomal du muon) permettrait donc de répondre à des questions toujours sans réponse. Plusieurs chercheurs ont déjà travaillé sur le cas du processus de diffusion neutron-neutron dans l'approximation de l'échange à un pion. Toutefois, il semblerait que cette approximation ne corresponde pas totalement à ce qu'on observe. Nous travaillons alors avec l'approximation de doux neutrinos. Cette méthode permet une approximation du comportement d'un nucléon off-shell lors de sa propagation par un nucléon on-shell. Nous calculons ici les émissivités d'une paire de neutrinos, de l'axion et du photon sombre à l'intérieur d'une supernova. Nous prenons le processus de refroidissement bremsstrahlung avec l'approximation de doux neutrinos pour nos calculs. Ces résultats permettraient d'utiliser des données expérimentales pour obtenir des valeurs numériques d'émissivité. / Dark matter fills the void in the current theory of gravity. Introducing dark matter models with axion like particles (theoretical particles that would represent a solution to the strong CP problem) or with dark photons (theoretical particles that could fix the muon anomalous magnetic moment problem) could answer multiple questions which remain unanswered. Many researchers worked on neutron-neutron diffusion with the one pion exchange approximation. However, it seems like this approximation is not representative of the observations. We will work with the soft neutrinos approximation instead. This method allows us to take the off-shell nucleons as if they were on-shell while they are propagating. We will compute the emissivities of neutrino pairs, axions and dark photons inside a supernova. We will use the bremsstrahlung cooling process with the soft neutrinos approximation. Those results will enable us to use experimental data to obtain numerical values of the emissivities.
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Microscopic cluster model of elastic scattering and bremsstrahlung of light nuclei / Etude microscopique de la diffusion élastique et du bremsstrahlung entre noyaux légers par un modèle en amasDohet-Eraly, Jérémy 12 September 2013 (has links)
Microscopic approaches enable one to study nuclear bound states as well as nuclear collisions in a unified framework.<p>At non-relativistic energies, all physical quantities are determined by the solutions of the many-body Schrödinger equation based on an interaction potential between nucleons.<p>The difficulty of solving this equation for collisions and taking the antisymmetrization principle into account restricts these approaches to light nuclei and requires the development of nuclear models based on some simplifying assumptions.<p>One of these assumptions, which is done in this work, is to consider that the nucleons are aggregated in clusters in the nuclear systems. <p><p>Another major problem of the microscopic description is the difficulty of determining a reliable interaction potential between nucleons.<p>In spite of many years of efforts to establish such potentials, none has yet been proved to accurately describe both the spectroscopic properties of nuclei and the reactions between light nuclei.<p>For this reason, many effective NN interactions, adapted to the model space and to the studied collision, have been built and used in microscopic models.<p>In parallel, for a few years, some efforts have been done to use in the microscopic models more realistic NN interactions, adjusted to reproduce the two-nucleon properties.<p>However, this requires solving much more accurately the Schrödinger equation by relaxing, for instance, the cluster assumption.<p>These approaches therefore need large computational times, which limits the size of the systems that can be studied.<p><p>In this work, a two-body realistic interaction has been adapted to the simple microscopic cluster model by using the Unitary Correlation Operator Method. This new realistic effective interaction has been adjusted so that the α+α elastic phase shifts obtained with the microscopic cluster model agree rather well with the experimental data.<p>This interaction has been used to study α+N and α+3He scattering.<p>The calculated phase shifts give a rather good agreement with experimental data without additional adjustment, without three-body interactions and with simple basis functions. <p><p>Besides this study of elastic scattering between light nuclei, this work deals with the nucleus-nucleus bremsstrahlung.<p>Previous microscopic models of nucleus-nucleus bremsstrahlung were based on a photon-emission operator fully neglecting the meson-exchange currents. <p>In this work, a microscopic cluster model of bremsstrahlung is developed, which implicitly takes them partially into account by using an extension of the Siegert theorem. <p>Then, the photon-emission operator can be deduced from the charge density rather than from the current density.<p>Although this extension of the Siegert theorem does not fully remove the nuclear-current dependence, the effects of the meson-exchange currents should be largely reduced, especially at low photon energy.<p><p>The microscopic cluster model of nucleus-nucleus bremsstrahlung developed in this work has been applied to the α+ α and α+N systems. This model is based on an effective NN interaction, which enables a good reproduction of the elastic phase shifts for the α+ α and α+N systems.<p>The agreement with experimental bremsstrahlung cross sections is rather good but the comparison between theory and experiment requires more numerous and more accurate data to be conclusive. With an extension to the p shell, the present model could also describe heavier cluster systems such as 12C+p and 16O+p for which experimental data exist at low energies.<p> / Doctorat en Sciences de l'ingénieur / info:eu-repo/semantics/nonPublished
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