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Day 1 - Tuesday, December 11
08:30 - 09:00 Registration
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09:00 - 09:10 Opening Session - José Lemos and Ilídio Lopes
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Session 1 - Chair: Ilídio Lopes
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09:10 - 10:00 Aldo Serenelli
The exquisite data provided by helioseismology and, more recently, by solar neutrino experiments allow us to determine the physical conditions in the solar interior. Our understanding of solar interior physics, represented by solar models, can then be tested precisely. In this talk, I will review the current status of solar models and the most recent results on solar neutrinos, and discuss some caveats in current models. I will then highlight some open questions for solar physics, stellar and particle physics

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The exquisite data provided by helioseismology and, more recently, by solar neutrino experiments allow us to determine the physical conditions in the solar interior. Our understanding of solar interior physics, represented by solar models, can then be tested precisely. In this talk, I will review the current status of solar models and the most recent results on solar neutrinos, and discuss some caveats in current models. I will then highlight some open questions for solar physics, stellar and particle physics

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10:00 - 10:50 Aaron Vincent
I will introduce the effects of dark matter capture in Sun-like stars, as they pass through the distribution of dark matter known to fill the Milky Way. I will focus on the effects of heat conduction by weakly interacting particles such as asymmetric dark matter: specifically, a reduction of central temperature and thus a significant change in the solar neutrino fluxes, as well as changes in the radius-dependent sound speed, reflected in high-precision helioseismology measurements. Such effects may help solve the solar abundance problem, a > 6-sigma discrepancy between the predicted and observed structure of the Sun in the Standard Solar Model, which has confounded solar physicists for over a decade. I will briefly discuss other effects of dark matter on stars, as well as complementary probes from laboratory experiments.

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10:50 - 11:20 Poster Session & Coffee Break
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11:20 - 12:10 Pat Scott
I will discuss recent progress in the hunt for axions and asymmetric dark matter using the Sun and other stars. First, I will present the results of global fits to axion and axion-like particle models, including constraints from horizontal branch stars, searches for solar axions, and white dwarf cooling. I will then present some preliminary results of explicit Monte Carlo simulation of energy transport in the Sun by dark matter with velocity- and momentum-dependent interactions with nucleons.

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12:10 - 12:30 Nadja Magalhães
General relativity can be used to fit the rotation curves of galaxies with less dark matter than it is necessary when other theories of gravitation are applied. In this approach a galaxy is modelled as low density baryonic dust in stationary, axially-symmetric rotation, in which case it has already been shown that non-linear gravitational effects play a significant role in the overall motion of matter. The fits can be used to determine mass densities as functions of galactocentric distances and heights, therefore yielding galactic masses. As a first approximation to their morphologies, we discovered that new information about the galaxies can be obtained from their mass-density functions. Our pproach is applied here to the galaxy UGC 128, whose results are compared to those previously obtained for NGC 2403. Studies comparing these two galaxies were published before, either assuming the existence of dark matter or using MOND. These two galaxies are at identical positions on the Tully-Fisher relation, having almost identical luminosities. As well, they have almost identical rotation velocities and they are morphologically very similar. However, they display large differences in surface brightness. Despite their almost identical rotational velocity profile, using our approach we found that their mass density profiles may be significantly different. In this poster we will display our results and highlight their implications for the understanding of the nature of dark matter.

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12:30 - 14:00 Lunch Break
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14:00 - 14:30 Poster Session
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Session 2 - Chair: Vítor Cardoso
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14:30 - 15:20 Jordi Isern
White dwarfs are the final remnants of low and intermediate mass main sequence stars. Because of electron degeneracy, their evolution is just a cooling process. The basic ingredients to understand their evolution are well identified (although not all of them completely understood), and there is at present an important observational background that allows to check the different models of cooling. The majority of white dwarfs can be imagined as a degenerate core made of a mixture of 12C, 16O plus several impurities that contains the bulk of mass and acts as an energy reservoir, surrounded by a semidegenerate envelope that controls the flux of energy from the interior to free space. Since the corresponding cooling rate can be obtained from their luminosity function or the secular drift of their period of pulsation, it is possible to consider them as a calorimeter turning around the center of the Galaxy. Therefore, these properties can be used to detect the existence of additional, unexpected, energy sources or sinks. In this talk I describe how white dwarfs can be used as detectors and I apply them to the case of axions.

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15:20 - 16:00 M. Ángeles Pérez-García
In this talk I will present recent progress on the study of dark matter models where gravitationally captured dark matter can self-annihilate inside a dense star (neutron star) and subsequently produce changes in the microscopic matter conditions. Depending on selected dark candidate mass and interaction cross-section to nucleons this fact could lead to a new mechanism to form even denser stars.

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16:00 - 16:30 Poster Session & Coffee Break
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16:30 - 17:20 Interaction of Primordial Black Holes with StarsMalcolm Fairbairn
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17:20 - 17:50 Discussion Panel - Chair: Joseph Silk
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19h30 Workshop Dinner
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Day 2 - Wednesday, December 12
Session 3 - Chair: Ana Mourão
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09:10 - 10:00 Laura Tolos
The equation of state (EoS) of dense hadronic matter is of crucial importance for the description of the static and dynamical properties of neutron stars. In this talk I will review the current status of the hadronic EoS for neutron stars, from the point of both ab-initio many-body approaches and phenomenological models. The theoretical predictions for the hadronic EoS will be compared to the data coming from both nuclear physics experiments and astrophysical observations, providing insights for future research.

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10:00 - 10:25 Oleksii Ivanytskyi
Based on recent experimental and theoretical hints on possible formation of a resonant four-neutron system we study effects of appearance of such a cluster in neutron rich baryon matter inside neutron stars. For this purpose we employ a relativistic mean field approach which includes nucleons, Δ-baryons as well as light nuclear clusters. The Pauli blocking which suppresses tetraneutrons and stable clusters is explicitly included to the model as well. Our analysis demonstrates that tetraneutrons are able to exist as the Bose-Einstein condensate. Such a condensate weakens the nucleon Cooper pairing and significantly suppresses formation of the superfluid phase inside neutron stars. Tetraneutrons are also found to strongly feed vector meson fields and suppress Δ-baryons leading to stiffening of equation of state.

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10:25 - 10:50 Marina Cermeño Gavilán
We consider self-annihilation of fermionic sub-GeV dark matter into metastable mediators inside white dwarfs (WDs). We assume these mediators decay into two photons after being produced. We calculate the luminosity of WDs due to these annihilations taking into account theenergy loss of the mediator and its finite lifetime in the dense stellar medium. Finally, using complementary sets of measurements ranging from cold white dwarfs in the M4 globular cluster and direct/indirect searches we discuss constraints on mediator lifetimes.

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10:50 - 11:20 Poster Session & Coffee Break
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11:20 - 12:10 Christoforos Kouvaris
I will discuss ways that compact star observations can set constraints on different dark matter candidates. In addition, I will entertain the possibility of asymmetric dark matter forming its own compact objects and I will argue that such objects could be detected and identified using a variety of techniques.

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12:10 - 12:30 Violetta Sagun
We apply the novel equation of state, which includes the surface tension contribution induced by the interparticle interaction and the asymmetry between neutrons and protons, to the study of neutron star properties. This equation of state is obtained from the virial expansion for the multicomponent particle mixtures that takes into account the hard-core repulsion between them. The considered model is in full concordance with all the known properties of normal nuclear matter, provides a high quality description of the proton flow constraints, hadron multiplicities created during the nuclear-nuclear collision experiments and equally is consistent with astrophysical data coming from neutron star observations and GW170817 merger. The found mass-radius relation for neutron stars computed with this equation of state is consistent with astrophysical observations. This talk will show how the induced surface tension (IST) equation of state opens an elegant way to describe the properties of matter across a very wide range of densities and temperatures.

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12:30 - 14:00 Lunch Break
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14:00 - 14:30 Poster Session
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Session 4 - Chair: José Lemos
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14:30 - 15:20 Pearl Sandick
The first stars formed from pristine hydrogen and helium at high redshift and were much more massive than typical stars of subsequent generations. If these stars formed near the centers of their dark matter minihalos, the dark matter would have contracted around the compact baryonic object. The most massive stars would have ended their lives by collapsing to black holes, leaving a black hole remnant surrounded by a dark matter spike. Furthermore, if the first stage of stellar evolution is a Dark Star phase during which the star is powered by dark matter annihilations, the first stars would have grown to be even larger, possibly even becoming supermassive, and leaving correspondingly larger black hole remnants. In this talk I’ll discuss potential signatures of the first stars via indirect detection of annihilation in their dark matter spikes, as well as existing constraints from various experiments.

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15:20 - 15:30 Asteroseismology constraints on dark photonsAdrián Ayala
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15:30 - 15:40 Carlos Frajuca
The authors have experience with the SCHENBERG Gravitation Wave detector which is a resonant-mass developed by the Brazilian GRAVITON. Its spherical antenna weighs 1150 kg and it is monitored by six ultralow noise parametric transducers and is connected to the outer environment by a suspension system designed to attenuate local noise, both seismic and non-seismic, operating in a temperature of 4 K. With all the acknowledgment acquired the idea of making an experiment to measure the speed of gravity took form. Using monocrystalline sapphire with very high mechanical and electrical Q´s, ultralow phase noise microwave sources, Finite Element Modelling designed suspensions, parametric microwave transducers, excellent properties of noise filtering of the resonant-mass detectors and the development of high-speed rotation machines guided the authors to the design of the experiment. The experiment will measure oscillations caused by gravitational interaction with an amplitude of the order of 0.1 am (10-19m). The main feature is a rotating mass that will generate a periodic tide signal at a very high frequency. in this work the optimization of such mass to reach the highest tide signal is shown.

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15:40 - 15:50 Ana Mourão
Polarimetric studies of stars, supernovae, clusters and galaxies are able to provide crucial information about the intrinsic properties of these objects. Polarimetry is also extremely important to understand the properties of the dust that might affect the observations and lead to systematic effects. In our work we investigate the instrumental polarization in FORS2- the FOcal Reducer and low dispersion Spectrograph at Very Large Telescope, ESO. With optical multiband sky observations in BVRI during full moon we were able to produced 2D maps of the the instrumental polarization. These maps are particularly relevant in polarimetric studies of extended sources.

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15:50 - 16:00 Nitin Shukla
e- e+ plasma-dark electromagnetism similarity establishes a (nearly) weaker-than-gravity bound on long-range dark matter self-interactions

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16:00 - 16:30 Poster Session & Coffee Break
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16:30 - 17:20 Anne Green
I will overview what astrophysical observations tell us about the properties of dark matter with particular focus on Primordial Black Holes (PBHs), black holes formed in the early Universe. The recent discovery of gravitational waves from mergers of ~10 Solar mass black hole binaries has (along with the lack of signal in WIMP detection experiments) led to increased interest in PBHs as a dark matter candidate. I will discuss the limits on their abundance, with particular emphasis on microlensing and dynamical constraints in the Solar mass region.

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17:20 - 17:50 Discussion Panel - Chair: Malcolm Fairbairn
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17:50 - 18:00 Closing Session
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