Global ETD Search

61	Applications of High-Resolution Astrometry to Galactic Studies Salim, Samir 11 September 2002 (has links) No description available. Physics, Astronomy and Astrophysics astrometry Milky Way stars gravitational lensing Galactic center catalogs
62	The Observational and Theoretical Tidal Radii of Globular Clusters in M87 Webb, Jeremy J. 10 1900 (has links) <p>Globular clusters have linear sizes (tidal radii) which are theoretically de- termined by their mass and by the gravitational potential of their host galaxy. However observationally, cluster sizes are simply a determination of where the cluster’s surface brightness profile becomes zero. This distance is also known as the limiting radius. While it is commonly assumed that the tidal radius and the limiting radius of a globular cluster are the same thing, it has yet to be validated. The purpose of this thesis is to explore the assumption that cluster tidal radii and limiting radii are equal by comparing the tidal radii of an observed and simulated globular cluster population.</p> <p>An established link between cluster tidal radii and limiting radii will yield new methods of utilizing globular clusters as tools for studying galaxies. If cluster sizes are truly imposed by the tidal field of the host galaxy, then tidal radii measurements can be used to trace the mass distribution within a galaxy, including the dark matter halo. Additionally, as we will demonstrate in this thesis, cluster sizes can also be used a tracer for the orbital anisotropy profile of a galaxy.</p> <p>To explore the assumption that tidal radii and limiting radii are equal, we utilize the globular cluster population of the Virgo giant M87. Unusually deep, high signal-to-noise images of M87 are used to determine the radius for approximately 2000 globular clusters. To compare with these observations, we simulate a globular cluster population that has the same characteristics to the observed M87 cluster population. These characteristics include cluster radial distribution, mass distribution, central concentration distribution and line of sight velocity dispersion. Placing these simulated clusters in the well-studied tidal field of M87, the orbit of each cluster is solved and the theoretical tidal radius of each cluster is determined. We compare the predicted relationship between cluster size and projected galactocentric distance found in our sim- ulation to observations in order to test whether a cluster’s tidal radius and limiting radius are equal. We find that for an isotropic distribution of cluster velocities, theoretical tidal radii are approximately equal to observed limiting radii. The simulation predicts the observed increase in cluster size with galac- tocentric distance, which is expected if tidal radii are dependent on the tidal field. Additionally, simulated cluster sizes are of the same order of magnitude as observed cluster sizes. However the simulation does underestimate cluster sizes in the inner regions of M87. To minimize the discrepancy between theory and observations, we further explore the effects of orbital anisotropy on cluster sizes, and suggest a possible orbital anisotropy profile for M87 which yields the best fit between theory and observations. Finally, we suggest multiple future studies which will aid in our understanding of tidal theory and in establishing a stronger link between tidal radii and limiting radii.</p> / Master of Science (MSc) Tidal Radius Globular Clusters M87 Gravitational Potential Milky Way Orbital Anisotropy External Galaxies External Galaxies
63	Populações e evolução do bojo e região central da Galáxia / Populations and the evolution of the bulge and central region of the Galaxy Moraes, Oscar Cavichia de 03 May 2012 (has links) O presente trabalho propõe uma abordagem abrangente para descrever a evolução da região central da Via Láctea, compreendendo-se aí o bojo, a barra e as interfaces dos mesmos com o limite interno do disco e com a região central do halo. Pretende-se investigar as propriedades químicas e cinemáticas destas estruturas, que são interconectadas, com o objetivo de separá-las e aplicar os resultados daí obtidos a um modelo de formação e evolução do bojo e da região interna do disco que descreva simultaneamente distintos aspectos da evolução da região central da Galáxia. Na primeira parte do trabalho, uma amostra de nebulosas planetárias (NPs) localizadas no disco interno e no bojo da Galáxia é utilizada para encontrar a distância galactocêntrica que melhor separa estas duas populações, do ponto de vista das abundâncias. Foram utilizadas escalas de distâncias estatísticas para o estudo da distribuição das abundâncias na interface bojo-disco. A aplicação do teste Kolmogorov-Smirnov mostrou que, em média, a população interna não segue o gradiente radial de abundâncias do disco na direção do centro galáctico. Baseado neste estudo, propõe-se uma distância galactocêntrica de 1.5 kpc para definir a interface bojo-disco. Na segunda parte do trabalho, foram realizadas observações espectrofotométricas de 21 NPs localizadas na direção do centro da Galáxia com o telescópio SOAR. Estes objetos estão localizados bem próximos ao plano galáctico na direção central da Via Láctea, onde não existem dados de NPs na literatura. Os resultados mostram que as NPs localizadas nesta região apresentam baixas abundâncias de oxigênio comparadas com as NPs do disco interno e de outras regiões do bojo. Os resultados indicam que o bojo apresenta uma complexa composição de populações estelares. Por um lado, a presença de nebulosas com baixas abundâncias mostra que o bojo pode ter se formado a partir de um disco galáctico antigo através de uma evolução secular. Por outro lado, existem alguns objetos do bojo para os quais as abundâncias coincidem com o limite do gradiente radial do disco nesta região. Esta é uma evidência para um bojo composto por duas ou mais populações: uma originada do disco fino, e outra originada do disco espesso. Na última parte do trabalho propõe-se a inclusão de fluxos radiais de gás em um modelo de evolução química para simular os efeitos de uma barra localizada no centro da Galáxia nas distribuições de abundâncias, densidade de gás e taxa de formação estelar (SFR). Os resultados das simulações indicam que os modelos com fluxos de gás apresentam uma SFR mais alta no bojo e que os perfis da SFR e da densidade de gás na região central são melhor reproduzidos após a inclusão dos fluxos radiais no modelo. As simulações indicam ainda que o gradiente de abundâncias do disco é mais plano para o caso da inclusão da barra. Estes resultados indicam que a barra e os fluxos de gás exercem um importante papel na formação de estrelas no centro das galáxias espirais barradas. / This project proposes a comprehensive approach to describe the evolution of the central region of the Galaxy, comprising the bulge, the bar and their interfaces with the inner disk and the central region of the halo. We intend to investigate the chemical and kinematic properties of these structures, which are interconnected, aiming to separate them and apply these results to a model for the formation and evolution of the bulge and inner disk, capable to describe simultaneously distinct aspects of the evolution of the central region of the Galaxy. First, a sample of planetary nebulae (PNe) located in the inner-disk and bulge of the Galaxy is used in order to find the galactocentric distance that better separates these two populations, from the point of view of abundances. Statistical distance scales were used to study the distribution of abundances across the disk-bulge interface. A Kolmogorov-Smirnov test was used to find the distance in which the chemical properties of these regions better separates. The results of the statistical analysis indicate that, on the average, the inner population has lower abundances than the outer. Additionally, for the $\\alpha$-elements abundances, the inner population does not follow the disk radial gradient towards the galactic centre. Based on our results, we suggest a bulge-disk interface at 1.5 kpc, marking the transition between the bulge and inner-disk of the Galaxy, as defined by the intermediate mass population. Second, we present spectrophotometric observations for a sample of 21 PNe located towards the galactic centre of the Galaxy. The abundances are derived based on observations in the optical domain made at the SOAR telescope. Their location is interesting since there are no observations of PNe in this region. The data show lower oxygen abundances compared to those from PNe located in the inner disk and other bulge regions. The results show that the bulge has a complex composition of stellar populations. The presence of PNe with low abundances indicates that the bulge might be formed from an old galactic disk through secular evolution. On the other hand, other objects from our sample have abundances compared to those from inner disk PNe. This is evidence that two or more populations might compose the bulge: one originated from the thin disk, and the other from the thick disk. Last, we propose a chemical evolution model that includes radial gas flows. This is done in order to mimic the effects of the galactic bar on the chemical abundances distributions and the gas density profiles and the star formation rate (SFR). The results of the models with radial flows point to a high SFR in the bulge and, additionally, the SFR and gas density profiles in the inner Galaxy are better reproduced after the inclusion of radial gas flows in the model. After including a specific velocity pattern for the bar, the results show a flattening of the radial abundance gradient. Our results indicate that radial gas flows may play an important role in the star formation near the centre of barred spiral galaxies. abundâncias químicas bulge chemical abundances chemical evolution disk espectroscopia evolução química Milky Way nebulosas planetárias planetary nebulae spectroscopy Via Láctea
64	The baryonic matter and geometry of the local group Tronrud, Thorold 13 March 2019 (has links) First, the baryonic content of simulated halos of virial masses between 5 x 10^{9} M_{\odot}$ to 5 x 10^{12} M_{\odot}$ in the APOSTLE project is examined in the context of the missing baryon problem. Baryonic particles in APOSTLE can be either stars or gas. Non-star-forming gas, or the circumgalactic medium (CGM) is further classified by temperature into the Cool CGM (CCGM, T < 10^{5} K), or the Warm-Hot CGM (WHCGM, T > 10^{5} K). APOSTLE halos are found to contain less than 60% of the expected mass of baryons (f_{b} = Ω{b}/Ω{m}, M_{b} = f_{b} x M_{200}) within their virial radius. The WHCGM contains 29% ± 10%, the CCGM 12% ± 5%, and the stars and star-forming gas 19% ± 5%. The metal content of the same halos is analyzed, and compared to the total metals produced by the stars within the virial radius. Over two thirds of the produced metals are retained within the halo, with 14% ± 3% in the WHCGM, 13% ± 4% in the CCGM, and 43% ± 9% in the stars and star-forming gas. Next, we focus on the overall distribution of matter within a 3Mpc radius from the Milky Way. Using the trends in APOSTLE volumes, I quantify both the ellipticity and orientation of this spatial distribution using the principal axes of the inertia tensor of the positions of these galaxies. The Zone of Avoidance has little impact on this result, and the short axis is aligned with that of the Supergalactic Plane, and is perpendicular to the vector separating the Milky Way and Andromeda galaxies. APOSTLE local group analogues are found to be similarly anisotropic, and like in the observed Local Group, the minor axis of that distribution is found to be perpendicular to the vector separating the two primaries. The angular momentum of the stellar disk shows weak alignment with the minor axis of the field galaxy distribution. In addition the simulations also suggest that the angular momenta of the two primary dark-matter halos tend to be anti-aligned. Additionally, stellar disks tend to orient themselves in the same direction as their halo. / Graduate Astronomy Cosmology Simulations Metallicity Local Group Milky Way Andromeda M31 Circumgalactic Medium Baryon Retention Missing Baryon Problem
65	Fast stars in the Milky Way Boubert, Douglas Philip January 2018 (has links) I present a comprehensive investigation of fast stars in the Milky Way, from brisk disc stars to stars escaping the Galaxy. My thesis is that fast stars are the smoking guns of extreme stellar collisions and explosions, and so can act as an intermediary to studying these theoretically-unconquered astrophysical processes. In Chapter 1 I give a history of fast stars, address what it means for a star to be fast, and describe the processes that accelerate stars. I concisely summarise the Gaia mission, whose recent data releases heavily influenced this thesis. Supernovae in binary systems can fling away the companion; if a runaway companion can be associated with a supernova remnant, then together they reveal the evolution that led to the supernova. However, these associations are difficult to establish. In Ch. 2, I develop a sophisticated Bayesian methodology to search the nearest ten remnants for a companion, by combining data from Gaia DR1 with a 3D dust-map and binary population synthesis. With Gaia DR2, I will identify companions of tens of supernova remnants and thus open a new window to studying late-stage stellar evolution. It is unknown why 17% of B stars are spinning near break-up; these stars are termed Be stars because of emission lines from their ejected material. Their rapid spin could be due to mass transfer, but in Ch. 3 I show this would create runaway Be stars. I demonstrate using a hierarchical Bayesian model that these exist in sufficient numbers, and thus that all Be stars may arise from mass transfer. The stars escaping the Milky Way are termed hypervelocity stars. In Ch. 4, I overturn the consensus that the hypervelocity stars originated in the Galactic centre by showing that a Large Magellanic Cloud (LMC) origin better explains their distribution on the sky. In Ch. 5 I present three ground-breaking hypervelocity results with Gaia DR2: 1) only 41 of the 524 hypervelocity star candidates are truly escaping, 2) at least one of the hypervelocity stars originates in the LMC, and 3) the discovery of three hypervelocity white dwarf runaways from thermonuclear supernovae.
66	Chemical Abundance Analysis of Population II Stars : The Summary Includes a Background in General Astronomy Jonsell, Karin January 2005 (has links) <p>We are made of stardust in the sense that most atomic nuclei around us have been formed by stars. Stars synthesise new elements and expel them to the interstellar medium, from which later new generations of stars are born. We can map this chemical evolution by analysing the atmospheric contents of old Galactic halo stars. I have done two such investigations. A vigourous debate is going on whether the oxygen-to-iron ratio varies strongly with the general metal-content of halo stars. In my first study, I made an abundance analysis of 43 halo stars, and found no support for such a variation. I have also found that there probably is a cosmic spread in the abundances of oxygen, magnesium, silicon, and calcium relative to iron for halo stars. This may be an indication that the halo was built up by subsystems with differences in the star formation rate. In my second study, I performed a thorough abundance analysis of the star HE0338-3945, which is strangely overabundant in both r- and s-elements. Several other stars have been found with abundance patterns curiously similar to this star, and I define new criteria for the class r+s stars. The abundance similarities among the r+s stars suggest a common formation scenario. However, as the s-elements usually are considered to be produced in binary systems of low mass, and r-elements in supernovae of Type II, this scenario is not obvious. In the article I discuss seven hypotheses, and several of them are dismissed.</p> Astronomy Astronomy Galactic evolution Halo Milky Way Oxygen r-element s-element Stellar abundances Astronomi Astronomy and astrophysics Astronomi och astrofysik
67	Chemical Abundance Analysis of Population II Stars : The Summary Includes a Background in General Astronomy Jonsell, Karin January 2005 (has links) We are made of stardust in the sense that most atomic nuclei around us have been formed by stars. Stars synthesise new elements and expel them to the interstellar medium, from which later new generations of stars are born. We can map this chemical evolution by analysing the atmospheric contents of old Galactic halo stars. I have done two such investigations. A vigourous debate is going on whether the oxygen-to-iron ratio varies strongly with the general metal-content of halo stars. In my first study, I made an abundance analysis of 43 halo stars, and found no support for such a variation. I have also found that there probably is a cosmic spread in the abundances of oxygen, magnesium, silicon, and calcium relative to iron for halo stars. This may be an indication that the halo was built up by subsystems with differences in the star formation rate. In my second study, I performed a thorough abundance analysis of the star HE0338-3945, which is strangely overabundant in both r- and s-elements. Several other stars have been found with abundance patterns curiously similar to this star, and I define new criteria for the class r+s stars. The abundance similarities among the r+s stars suggest a common formation scenario. However, as the s-elements usually are considered to be produced in binary systems of low mass, and r-elements in supernovae of Type II, this scenario is not obvious. In the article I discuss seven hypotheses, and several of them are dismissed. Astronomy Astronomy Galactic evolution Halo Milky Way Oxygen r-element s-element Stellar abundances Astronomi Astronomy and astrophysics Astronomi och astrofysik
68	Decomposition of the Globular Cluster NGC 6397 Tsui, Hong 06 1900 (has links) The kinematics and white dwarf distribution have been studied for the Globular Cluster NGC 6397. The data was obtained from NASA’s Hubble Space Telescope in 2005. In particular, we used the images of a field 5’ Southeast of the core of NGC 6397 from Advanced Camera for Surveys to conduct our analyses. The first part of the study is about the kinematics of the globular cluster. Isotropy of velocity distribution and cluster rotation have been considered. As anticipated, this relaxed cluster exhibited no strong signs of anisotropy. However, there appears to be some level of rotation. The rotational motion turns out to be mu sub alpha cos(delta) = 3.88 ± 1.41 mas yr −1 and mu sub delta = −14.83 ± 0.58 mas yr −1. This result is not entirely expected and deserves further investigation in future studies. The second of the thesis is based on white dwarf populations in the globular cluster and the Galactic Bulge. As a first glance, there appears to be a lacking of white dwarfs at the age of approximately 0.6 Gyr. Further investigation reveals this to be statistically insignificant. Through this analysis, another pattern of white dwarf abundance is discovered. There appeared to be much more stars at the age between 0.9 − 2.0 Gyr. This could be a manifestation of modeling error. As the final consideration of this thesis, white dwarf candidates in the Galactic Bulge are illustrated. Approximately 10 candidates are found at the most probable location of stars in the Bulge. The analyses conducted in this thesis set stage for further development in understanding of globular clusters. In particular, the rotation analysis raises curiosity about the dynamics of NGC 6397 in the plane of the sky. Moreover, the velocity distribution analysis confirms properties and theories pertaining to globular clusters. NGC 6397 white dwarf rotation galactic bulge velocity distribution globular cluster Jeans mass Jeans length anisotropy Milky Way
69	The local radio sky : high frequency-resolution single-dish studies of polarised Galactic synchrotron emission around 1.4 GHz Leclercq, Indy January 2017 (has links) Polarised synchrotron emission from the Milky Way is of interest for its role as a foreground to the polarised CMB and as a probe of the interstellar medium. The Galactic ALFA Continuum Transit Survey (GALFACTS) and the Global Magneto-Ionic Medium Survey (GMIMS) are two ongoing surveys of the diffuse polarised emission around 1.4 GHz, with wide bandwidths and high frequency-resolution. In this thesis, I use early data from GALFACTS to investigate the behaviour of polarised, diffuse Galactic synchrotron emission. I also analyse GMIMS total intensity data. I derive a rotation measure (RM) map of the GALFACTS sky using a combination of RM-synthesis and linear angle fitting, commenting on the structure of the maps in general and on specific regions in particular. Overall I find that the maps are rich in features, and probe the RM structure of the extended Galactic emission with reasonable accuracy. I also derive the Angular Power Spectrum (APS) of the polarised emission for thirty-one 15 by 15 degree subregions across the GALFACTS data. I compute the E- and B-modes (E+B) and the scalar APS of the polarised emission (PI). I parametrise the APS by fitting a power law to the data. Comparing the E+B APS to the PI APS shows that E+B is consistently steeper across the sky. The APS data is also used to estimate the level of foreground contamination of the CMB B-mode by the synchrotron emission. I find that the slope of the APS averaged over high-latitude, low-emission subregions agrees exactly with that of the Planck 30 GHz polarised emission, thus setting an upper limit to the synchrotron contamination of CMB B-modes. Finally, I evaluate the spurious, systematic, temperature zero-level offset and associated uncertainty in preliminary GMIMS total intensity maps, finding a lower limit of ±0.26 K. I also make spectral index maps made using the GMIMS data and the Haslam et al. (1982) 408 MHz map, improving upon previous spectral index maps in the literature. 523.1
70	O campo magnético da Via Láctea e a composição química dos raios cósmicos detectados no Observatório Pierre Auger / The Milky Way's magnetic field and the chemical composition of the cosmic rays detected at the Pierre Auger Observatory Selmi-Dei, Daniel Pakk, 1978- 02 February 2012 (has links) Orientador: Carola Dobrigkeit Chinellato / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-19T15:55:43Z (GMT). No. of bitstreams: 1 Selmi-Dei_DanielPakk_D.pdf: 9650136 bytes, checksum: a6af22f88f369a8903480bc20071c354 (MD5) Previous issue date: 2012 / Resumo: Esta tese apresenta um estudo das deflexões nas trajetórias de raios cósmicos com energia ultra-alta (> 1018 eV) devido à sua propagação pelo campo magnético da Via Láctea. Partindo de dados coletados no Observatório Pierre Auger, localizado na Argentina, a técnica do backtracking foi aplicada sob diversas hipóteses relativas à carga elétrica do núcleo primário. Uma situação histórica é feita desde a época da descoberta da radiação cósmica até as últimas técnicas de detecção desenvolvidas por Pierre Auger, descobridor dos chuveiros atmosféricos extensos. A natureza das cascatas é descrita para o entendimento de como direções de chegada e energias são inferidas através dos experimentos de hoje. Alguns detalhes do espectro do uxo de raios cósmicos nas energias mais altas são expostos. As metodologias relativas aos telescópios de uorescência e ao arranjo de superfície, empregados no Observatório Auger, são introduzidas. É estabelecida uma relação entre ambas as técnicas de detecção e alguns resultados importantes, obtidos nos últimos anos pela Colaboração Auger, são apresentados. É feita uma descrição da dinâmica de campos magnéticos em plasmas astrofísicos e de dados observacionais da rotação de Faraday para embasar a escolha dos modelos de campo magnético galácticos. A magnetohidrodinâmica também é usada para explicar por que é interessante considerar certos objetos aceleradores candidatos a fontes de raios cósmicos. A distribuição de matéria na Via Láctea é então caracterizada em relação aos dados de evolução estelar e passa a ser assumida a hipótese de que a nucleossíntese elementar ocorre de modo semelhante em outras galáxias. Em seguida, são definidos os modelos utilizados para a descrição dos campos magnéticos nas regiões do bojo, disco e halo da galáxia. A superposição de um modelo da componente irregular também é considerada. A técnica do backtracking de antipartículas (e, equivalentemente, o forwardtracking de partículas) é descrita segundo um novo método numérico de passos adaptativos introduzido neste trabalho. Algumas ferramentas de análise são propostas a partir dos dados de reconstrução das trajetórias. Em última análise, é demonstrado que esse método desenvolvido concorda com o método numérico de Runge e Kutta de quarta ordem. Os resultados apresentados nesta tese levam à conclusão de que se os modelos presentes descrevem aproximadamente o campo magnético de larga escala da Via Láctea, então raios cósmicos com energia ultra-alta são signicantemente de etidos durante a propagação. Para um evento real detectado no Observatório Auger, a escolha da composição química compatível com núcleos produzidos nas reações de nucleossíntese estelar permitiu indicar regiões da Via Láctea que podem abrigar objetos astrofísicos candidatos a fonte. Assumindo que um magnetar galáctico ativo conhecido radie partículas com E > 1019 eV, foi possível prever excessos do uxo bem localizados em certas direções do céu. Já a depleção desse uxo na direção do Aglomerado de Virgem pode ser explicada através da imposição de limites na composição química da radiação cósmica com incidência normal ao plano galáctico. Por último, sob a hipótese de que AGNs sejam as fontes dos núcleos atômicos ultra-energéticos observados, uma relação entre composição química e energia da partícula primária é derivada / Abstract: This thesis presents a study of the deflections of ultra-high energy (> 1018 eV) cosmic rays caused by its propagation through the large scale magnetic field of the Milky Way. From data collected by the Pierre Auger Observatory, in Argentina, the backtracking technique was applied under several hypotheses relative to the electric charge of the primary nucleus. A historical review is given since the discovery of the cosmic radiation until the last detection techniques developed by Pierre Auger, who was the discoverer of extensive air showers. The nature of the cascades is described for an understanding about how the arrival directions and energies are inferred from experiments performed today. Some details regarding the spectrum of the cosmic ray flux at the highest energies are exposed. The methodologies relative to the fluorescence telescopes and the surface array, employed at the Auger Observatory, are introduced. A relation is established between both techniques of detection and some important results obtained in the last years by the Auger Collaboration are presented. A description of the magnetic field dynamics in astrophysical plasmas and the observational data of Faraday rotation serve as a basis for the choice of galactic magnetic field models. Magnetohydrodynamics is also used to explain why it is interesting to consider certain objects as candidates for the source and acceleration of cosmic rays. The Milky Way is then characterized in respect to stellar evolution data and the hypotheses that the nucleosynthesis of the elements occurs in a similar way in other galaxies is assumed. Finally, models to describe the magnetic fields in the bulge, disk and halo regions are defined. The superposition of a model for the irregular component is also considered. The backtracking technique of antiparticles (and equivalently, the forwardtracking of particles) is described according to a new numerical adaptive stepsize method introduced in this work. Some analysis tools are proposed based on data from the reconstructed trajectories. Lastly, it is shown that the method developed here agrees with the fourth-order Runge-Kutta numerical method. The results presented is this thesis lead to the conclusion that if the present models describe approximately the large scale magnetic field of the Milky Way, then ultra-high energy cosmic rays are significantly de ected during propagation. For a real event detected at the Auger Observatory, the choice for a chemical composition compatible with the nuclei produced in stellar nucleosynthesis reactions allowed to pinpoint regions inside the MilkyWay that can house astrophysical objects as candidate sources. Assuming that a known active galactic magnetar radiates particles with E >1019 eV, it was possible to predict well localized ux excesses in certain directions of the sky. The depletion of that flux in the direction of the Virgo Cluster can be explained by the imposition of limits on the chemical composition of cosmic radiation with incidence normal to the galactic plane. In the last place, under the hypothesis that AGN are sources of the observed ultra-high energy atomic nuclei, a relation between chemical composition and particle energy is derived / Doutorado / Física / Doutor em Ciências Observatório Pierre Auger Raios cósmicos Campos magnéticos Via Láctea Pierre Auger Observatory Cosmic rays Magnetic fields Milky Way

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