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1	Isochoric heating of copper to Warm Dense Matter state using protons produced through laser solid-laser interactions Feldman, Samuel Henry 24 July 2013 (has links) This thesis examines the equation of state of copper at Warm Dense Matter states, between 1-100 eV and .1-10 times solid density. Protons accelerated off a thin metal foil irradiated with a high intensity laser beam flash heat solid density copper to between 5-10 eV before significant expansion occurs. The measured temperature and expansion are compared against simulations using various equations of states. The production and characterization of the laser system and proton beam used to heat the matter is also presented. / text Warm Dense Matter WDM Laser Proton
2	MEASURING NEUTRON STAR RADII VIA PULSE PROFILE MODELING WITH NICER Özel, Feryal, Psaltis, Dimitrios, Arzoumanian, Zaven, Morsink, Sharon, Bauböck, Michi 18 November 2016 (has links) The Neutron-star Interior Composition Explorer is an X-ray astrophysics payload that will be placed on the International Space Station. Its primary science goal is to measure with high accuracy the pulse profiles that arise from the non-uniform thermal surface emission of rotation-powered pulsars. Modeling general relativistic effects on the profiles will lead to measuring the radii of these neutron stars and to constraining their equation of state. Achieving this goal will depend, among other things, on accurate knowledge of the source, sky, and instrument backgrounds. We use here simple analytic estimates to quantify the level at which these backgrounds need to be known in order for the upcoming measurements to provide significant constraints on the properties of neutron stars. We show that, even in the minimal-information scenario, knowledge of the background at a few percent level for a background-to-source countrate ratio of 0.2 allows for a measurement of the neutron star compactness to better than 10% uncertainty for most of the parameter space. These constraints improve further when more realistic assumptions are made about the neutron star emission and spin, and when additional information about the source itself, such as its mass or distance, are incorporated. dense matter equation of state gravitation pulsars: general stars: neutron
3	Superfluid spherical Couette flow and rotational irregularities in pulsars Peralta, Carlos Andres Unknown Date (has links) (PDF) Small amplitude rotational irregularities are observed in a number of rotation-powered pulsars. They fall into two classes: (i) glitches, defined as abrupt increases in the angular velocity of a pulsar (accompanied sometimes by changes in the angular acceleration Ω), of which 286 have been observed in 101 objects; and (ii) timing noise, a continuous stochastic fluctuation in phase, or, which is observed mostly in young and adolescent pulsars (with ages ≥ 10 4 yr). Both classes of irregularity seem to arise from some mechanism that couples the angular momentum of the solid crust and superfluid core of the star, which is activated suddenly when differential rotation exceeds a threshold. Coupling mechanisms proposed to date include catastrophic vortex unpinning in the inner crust, triggered by starquakes; vortex creep, due to thermally activated quantum tunnelling; superfluid-superconductor interactions in the core; and superfluid instabilities. The associated theories are phenomenological, not predictive.
4	Constraining the Neutron Star Equation of State Olofsson, Klara January 2022 (has links) Neutron stars are stellar objects of extreme properties. The dense core enables usto study nuclear matter beyond saturation density. The exact composition of matterat such densities is not yet established, but the thermodynamic states of the matteris theoreticized by the Equation of State (EOS). The EOS cannot be derived analyt-ically and is dependent on constraints from neutron stars and nuclear experiments inlaboratories on earth. Recent advances in astrophysical experiments have probed newconstraints on the EOS by studying properties such as mass, radius and tidal deformabil-ity of neutron stars. Especially the possibility to detect gravitational waves from mergingbinary systems by the LIGO/VIRGO collaboration and the mass-radius measurementsby NICER have contributed a great deal. Constraints from terrestrial experiments havebeen derived by studying matter at supra saturation density in Heavy Ion Collisions andby determining the neutron skin thickness. In this work, an overview of neutron stars,dense matter and the EOS is presented. Further, results of studies aiming to determineand constrain the EOS are reviewed. Even though there is consensus about some neutronstar properties among different research groups, there are still major uncertainties as allresult depend on a relatively small set of observational data. Therefore, the EOS can stillbe considered to be far from precise and the knowledge of the true neutron star matterremains undisclosed. neutron star equation of state dense matter Engineering and Technology Teknik och teknologier
5	NEUTRON STAR MASS–RADIUS CONSTRAINTS OF THE QUIESCENT LOW-MASS X-RAY BINARIES X7 AND X5 IN THE GLOBULAR CLUSTER 47 TUC Bogdanov, Slavko, Heinke, Craig O., Özel, Feryal, Güver, Tolga 07 November 2016 (has links) We present Chandra/ACIS-S subarray observations of the quiescent neutron star (NS) low-mass X-ray binaries X7 and X5 in the globular cluster 47 Tuc. The large reduction in photon pile-up compared to previous deep exposures enables a substantial improvement in the spectroscopic determination of the NS radius and mass of these NSs. Modeling the thermal emission from the NS surface with a non-magnetized hydrogen atmosphere and accounting for numerous sources of uncertainties, we obtain for the NS in X7 a radius of R = 11.1(-0.7)(+0.8) km for an assumed stellar mass of M = 1.4 M-circle dot (68% confidence level). We argue, based on astrophysical grounds, that the presence of a He atmosphere is unlikely for this source. Due to the excision of data affected by eclipses and variable absorption, the quiescent low-mass X-ray binary X5 provides less stringent constraints, leading to a radius of R = 9.6(-1.1)(+0.9) km, assuming a hydrogen atmosphere and a mass of M. =. 1.4 Me. When combined with all existing spectroscopic radius measurements from other quiescent low-mass X-ray binaries and Type I X-ray bursts, these measurements strongly favor radii in the 9.9-11.2 km range for a similar to 1.5 M-circle dot NS and point to a dense matter equation of state that is somewhat softer than the nucleonic ones that are consistent with laboratory experiments at low densities. dense matter equation of state stars: neutron
6	Measurements of the K-shell opacity in solid-density plasmas heated by an X-ray Free Electron Laser Preston, Thomas Robert January 2017 (has links) The advances achieved using X-ray Free Electron Lasers such as the Linac Coherent Light Source (LCLS), have revolutionised the routine production of uniform solid-density plasmas. Pulses of X-rays above 1 keV and with durations shorter than 100 fs attaining intensities on target of around 10<sup>17</sup> Wcm<sup>-2</sup> are now routinely created. Through simple single-photon photoionization events with atoms in ambient solid conditions, it is possible to create uniform samples that are simultaneously hot, dense, and highly ionized which may be easily modelled. This thesis describes measurements of the spectrally-resolved X-rays emitted from solid-density magnesium targets of varying sub-μm thicknesses isochorically heated by an X-ray laser. The data exhibit a thickness-independent source function, allowing the extraction of a measure of the opacity to K-shell X-rays within well-defined regimes of electron density and temperature, extremely close to Local Thermodynamic Equilibrium conditions by fitting to the simple 1D slab solution of the equation of radiative transfer. The deduced opacities at the peak of the K-α transitions of the ions are consistent with those predicted by detailed atomic-kinetics calculations. The extracted opacities transpire to be robust to a plethora of variations in X-ray drive conditions, including the shape, pulse-length, and energy content. Furthermore the approximations in using the 1D slab solution are examined in detail and found to be good. A full three-dimensional model of the plasma is advanced which includes attenuation, line-of-sight effects, full longitudinal and transverse gradients, and photon time-of-flight effects. The results from this model are found to also agree with the simpler 1D slab solution. This novel method of elucidating opacities may complement other methods based on absorption and could be important for further benchmarking of opacities in solar-interior relevant conditions.
7	Investigations of high pressure phase diagrams of MgO-SiO2 systems with laser shock compression / Etude des diagrammes de phase des systèmes MgO-SiO2 à hautes pressions générées par chocs laser Bolis, Riccardo Maria 12 October 2017 (has links) La découverte récente d’un grand nombre d’exoplanètes et en particulier des planètes potentiellement habitables suscite une grande fascination. Pour modéliser les intérieurs de ces planètes, il est crucial de connaître avec précision les propriétés physiques et les équations d’état des composants planétaires. Ces matériaux se trouvent à des conditions de pressions et températures extrêmes ( 1-100 Mbar, 10^3-10^4 K), correspondantes à celles de la matière dense et tiède ou Warm Dense Matter (WDM). La description théorique de cette matière a progressé grâce aux calculs ab initio, mais reste complexe. Les données expérimentales sont fondamentales dans ce contexte.Ce projet de thèse porte sur l’étude expérimentale de trois matériaux importants pour la géophysique, le MgO, MgSiO3 et Mg2SiO4 dans le domaine ≈ 0.5-10 Mbar. Ces trois matériaux en fait sont les pôles purs magnésiens du (Fe, Mg)SiO3 and (Fe, Mg)2SiO4 qui sont parmi les composantes plus abondantes du manteau terrestre et très probablement des manteaux du Super-Terres et des noyaux des planètes géantes. Pour amener ces matériaux aux conditions typiques des intérieurs planétaires on a utilisé la technique de chocs laser. En particulier, nous avons réalisé trois campagnes expérimentales sur des grandes installations: LULI2000 (Ecole Polytechnique, France), GEKKOXII (Osaka University, Japan), MEC à LCLS (SLAC, USA). Pour chaque campagne, on a utilisé une technique différente. Sur LULI2000 et GEKKOXII nous avons étudié les propriétés de MgO, MgSiO3 et Mg2SiO4 liquide et la fusion avec des chocs décroissants couplés avec des diagnostiques optiques. Sur LULI2000 on a étudié les propriétés électroniques et structurelles du MgO liquide avec la spectroscopie XANES. Sur MEC, on a conduit une expérience de diffraction X pour déterminer les changements structuraux induits par des chocs stationnaires dans le régime solide sur le MgSiO3 et le Mg2SiO4. Dans leur ensemble, les résultats de ces expériences impliquent une révision des diagrammes de phase des matériaux étudiés. En particulier, on a déterminé un nouveau point de fusion pour le MgO (à 470 ± 40 GPa et 9860 ± 810 K), on a résolu une controverse sur la présence d’une transformation liquide-liquide dans le diagramme de phase du MgSiO3 (qui concernait une région autour de ~ 400 GPa sur la Hugoniot) et on a obtenu pour la première fois des évidences de la amorphisation de la Forsterite (Mg2SiO4 cristal) sous choc (à ~ 50 GPa sur la Hugoniot). En plus on a obtenu des informations sur la réflectivité (liée à la conductivité) pour le trois matériaux, et les données de spectroscopie XANES ont permis de comprendre le mécanisme de fermeture du gap (métallisation) du MgO sous effet de la température. / Two decades of exoplanet discoveries brought the physics of planetary interiors among the topics of broad and current interests. To advance in this field, one of the key ingredient is the knowledge of the equation of states and physical properties of planetary constituents. At the extreme conditions of planetary interiors ( 1-100 Mbar, 10^3-10^4 K), matter lies in the Warm Dense Matter (WDM) regime and theoretical descriptions are not trivial. Important progress have been done with ab-initio calculations based on differential functional theories, but such calculations need to be validated by experiments.In this thesis, we experimentally characterized phase diagrams and physical properties of MgO, MgSiO3 and Mg2SiO4 at conditions relevant for planetary science (0.5-10 Mbar). The studied compounds are the Mg end members of (Fe, Mg)SiO3 and (Fe, Mg)2SiO4 that are among the most abundant components of Earth’s mantle and are also thought to be abundant in Super-Earth’s mantle and giant planet cores. To bring these materials to planetary interior conditions we performed laser shock compression experiments at three high power laser facilities: LULI2000 (France), GEKKOXII (Japan), MEC at LCLS(USA). At LULI2000 and GEKKOXII we investigated the liquid properties and melting of MgO, MgSiO3 and Mg2SiO4 using decaying shocks coupled to visible diagnostics. At LULI2000 we studied with XANES spectroscopy MgO in the WDM regime highlighting its metallisation mechanism and structural properties in the liquid phase. Finally, at the MEC end station of LCLS, we used X-ray diffraction to measure shock induced structural changes on MgSiO3 and Mg2SiO4 in the solid region of their phase diagrams. Altogether these works, obtained with different diagnostics, imply a revision of the phase diagrams of the studied compounds. In particular we determined a new experimental melting point for MgO (at 470 ± 40 GPa and 9860 ± 810 K), we ruled out the occurrence of an MgSiO3 liquid-liquid transition (supposed to occur at ~ 400 GPa along the Hugoniot) and we evidenced for the first time the occurrence of an amorphous phase along the Forsterite (Mg2SiO4 crystal) Hugoniot (at ~50 GPa). Planetologie Laser choc Matière tiede et dense Planetology Laser shock Warm dense matter
8	Nuclei, Nucleons and Quarks in Astrophysical Phenomena Al Mamun, Md Abdullah 20 September 2019 (has links) No description available. Astrophysics Nuclear Physics Physics Theoretical Physics Nuclei nucleons quarks astrophysics nuclear physics neutron stars gravitational waves phase transition Love number dense matter cold dense matter QCD phase transition level density pairing properties superconductivity superfluidity
9	Study of high energy density matter through quantum molecular dynamics and time resolved X-ray scattering White, Thomas G. January 2014 (has links) The warm dense matter regime (WDM), defined by temperatures of a few electron volts and densities comparable with solids, is a complex state of matter where multi-body particle correlations and quantum effects play an important role in determining the overall structure and equation of state. The study of WDM states represents the laboratory analogue of the astrophysical environments found in the cores of planets and in the crusts of old stars, but also has practical applications for controlled thermonuclear fusion. Time resolved X-ray diffraction is used to study the temporal evolution of a sample from solid state towards WDM, either after irradiation with an intense proton/electron beam, in carbon samples, or direct laser illumination, in thin gold nanofoils. The electron-ion equilibration time is extracted through the use of the two-temperature model and in highly excited carbon shown to be longer than previously thought, this is attributed to strong ion-ion coupling screening the interaction (coupled mode theory). Calculation of the dynamic ion-ion structure factor is performed using orbital-free density functional theory (OF-DFT) and shown to compare well with Kohn-Sham DFT in both the static and dynamic cases. Experimental verification of these results is vital and measurement of the microscopic dynamics of warm dense aluminium have been successfully demonstrated through inelastic X-ray scattering. Using the self-seeded beam at the linear coherent light source (LCLS) scattering at a small momentum exchange allowed the first direct measurement of ion acoustic waves in WDM. This data provides the basis for a direct experimental test of many dense plasma theories through direct comparison with the ion-ion dynamic structure factor. 539.7
10	Chocs laser sur le diamant, l hélium et l hydrogène: une etude experimentale de la ''Warm Dense Matter. Brygoo, Stéphanie 20 November 2006 (has links) (PDF) La connaissance de l'équation d'état de systèmes d'hélium, d'hydrogène et de diamant dans le domaine des hautes pressions et températures est un problème ouvert, très controversé et présentant des applications astrophysiques importantes. Les approches théoriques pour cet état de la matière à l'interface de la physique de la matière condensée et de la physique des plasmas, appelé dans la littérature Warm Dense Matter, ne sont pas encore entièrement satisfaisantes. Une des raisons est qu'il n'existe pratiquement pas de données expérimentales pour valider les approximations dans ce domaine du diagramme de phase. En effet les approches statiques ou dynamiques seules ne peuvent atteindre ces états. En 2002, une première démonstration de la possibilité du couplage des compressions statiques et dynamiques, par génération de chocs laser dans des presses à enclumes de diamant, a ouvert la voie de l'étude de l'équation d'état de la matière très dense et chaude. Dans ce travail de thèse, nous avons optimisé les cibles et développé une nouvelle métrologie basée sur le quartz comme système de référence dans le but de réduire au maximum les barres d'erreur. Des mesures précises de la pression, la température, la densité et la réflectivité peuvent ainsi être obtenues. Cette méthode a ensuite été appliquée à différents systèmes. De nombreux résultats ont alors été obtenus sur le diamant (existence d'un maximum sur le courbe de fusion), sur l'hélium (va! lidation du modèle de Saumon-Chabrier), sur l'hydrogène (passage continue entre un état isolant et un état conducteur) et sur les mélanges hydrogène/hélium (pas de signe évident de séparation de phase). Equation d'état Choc laser Précompression Diamant Hélium Hydrogène Métrologie quartz Warm dense matter

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