Global ETD Search

101	Candidats (proto-)amas de galaxies à grand redshift vus par le CFHT / High-redshift galaxy (proto-)cluster candidates as seen by the CFHT Clarenc, Benjamin 11 September 2018 (has links) Les galaxies locales ont des propriétés différentes selon leur environnement : couleur, morphologie, fraction de gaz, etc. Cette différentiation s'est opérée durant leur formation. Les observations indiquent que ce pic d'activité de formation stellaire a eu lieu vers z=2 et que les environnements denses étaient à cette époque des lieux de formation stellaire très intense, soit l'inverse d'aujourd'hui. C'est en observant les progéniteurs des amas massifs actuels que l'on pourra comprendre l’origine de ces différences. Mais les (proto-)amas à grand z sont difficilement observables. De bons candidats sont les galaxies sub-millimétriques, qui tracent directement la formation stellaire. Grâce aux observations des satellites Planck, Herschel et Spitzer, un échantillon de 82 candidats a été construit : SPHerIC (Spitzer–Planck–Herschel infrared clusters). Ses données indiquent des sources compatibles avec les progéniteurs des amas massifs locaux. 13 de ces champs ont été observés par le CFHT. J’ai tiré parti de ces nouvelles données afin de rendre SPHerIC plus robuste. Après avoir développé un pipeline photométrique pour créer les catalogues de sources JKs, j'ai généré des cartes de densité surfacique de galaxies par tranches de couleur J-Ks. J'ai défini 8 couleurs J-Ks à partir des modèles de Berta et al. (2013) pour contraindre le redshift des galaxies. Je quantifie la coïncidence entre les positions des surdensités JKs, des surdensités IRAC-rouges et des sources SPIRE-rouges. Les diagrammes couleur-magnitude (J-Ks) vs Ks couplés aux modèles de Kodama et al. (1998) semblent indiquer la présence d’une séquence rouge à z~2 pour 12 des 13 champs. Les diagrammes couleur-couleur [3.6]-[4.5] vs (J-Ks) des sources IRAC-rouges sont eux compatibles avec les modèles de galaxies en phase de formation stellaire de Berta et al. (2013), un résultat compatible avec ceux de Planck et Herschel. Toutes les analyses de nos données photométriques convergent vers la conclusion que nos candidats sont de réelles structures à grand redshift et à formation stellaire intense. Après l'observation spectroscopique de sources SPHerIC au télescope de 30 m de l'IRAM, je confirme notamment l'existence de 2 structures à z>2. À partir des flux CO, je dérive la luminosité infrarouge et le SFR dont les valeurs semblent indiquer là encore des structures en phase de formation stellaire intense. J'ai aussi contribué au projet spatial Euclid en étudiant les variations de la PSF de la caméra VIS en fonction du type d'objet observé et de sa position sur le plan focal, et je montre que les variations sont faibles pour les étoiles et galaxies standards. / The properties of local galaxies (color, morphology, gas fraction, etc.) greatly depend on their environment. The differentiation occurred during their assembly. Current observations indicate that the peak of star formation occurred around z=2 and that dense environments used to be cradles of intense star formation, unlike today. This differentiation may be explained by observing the high-z progenitors of today’s most massive systems. However, such sources are rare. Good candidates are sub-millimeter galaxies, because they directly trace star formation. A sample of 82 such candidates named SPHerIC (Spitzer–Planck–Herschel infrared clusters) was made from the data of these three satellites. From them, 13 have been observer by the CFHT. I extracted as much information as I could from those new data in order to make SPHerIC more robust. After making JKs source catalogs with a self-made photometric pipeline, I made galaxy surface density maps in J–Ks color slices. I defined 8 colors using Berta et al. (2013) galaxy templates to constrain the redshift of galaxies. I show the coincidence between the position of JKs and IRAC-red overdensities with the position of SPIRE red sources. JKs color–magnitude diagrams (J–Ks vs Ks) along with models from Kodama et al. (1998) may exhibit a z~2 red sequence in 12 out of 13 fields. NIR color–color diagrams ([3.6]–[4.5] vs J–Ks) of IRAC-red sources are compatible with starforming models from Berta et al. (2013), also compatible with Planck and Herschel results. The analyses of our photometric data all converge toward the fact that our candidates are genuine high-z star-forming structures. From spectroscopic observations at the IRAM/30m telescope, I confirm for instance 2 structures at z>2. Infrared luminosities and SFRs derived from CO fluxes are consistent with high-SFR sources. In parallel, I have been involved in the Euclid Consortium. I studied the PSF variations of the VIS imager w.r.t. the spectral type of observed objects and their position on the focal plane. I show there is a limited impact on the PSF as long as the stars and galaxies are standard. Cosmologie Amas de galaxies Galaxies infrarouges Grand redshift Cosmology Galaxy clusters Infrared galaxies High redshift
102	The high-redshift clusters occupied by bent radio AGN (COBRA) survey Golden-Marx, Emmet Gabriel 31 January 2021 (has links) Galaxy clusters are the largest gravitationally-bound structures in the universe. Since clusters are comprised of hundreds of galaxies, hot X-ray emitting gas, and dark matter, they offer a unique laboratory in which to explore the evolution of large-scale structure and galaxies. To understand how massive, low-redshift galaxy clusters evolve to become what is observed in the modern universe, astronomers need to trace the evolution of progenitor clusters. Though there are thousands of well-studied low-redshift clusters, there are significantly fewer spectroscopically confirmed high-redshift clusters. Because most massive galaxies host supermassive black holes, one cluster tracer at both low and high redshift are active galactic nuclei (AGNs). Specifically, bent, double-lobed radio sources are commonly found in clusters. I find high-redshift clusters hosting bent AGNs and explore their evolution and red sequence galaxies over cosmic time. To characterize cluster evolution, I examine the galaxy populations surrounding each AGN to determine if bent AGNs are commonly found within clusters with evolved red sequence populations. I then identify evolution among the member galaxies in the clusters, I estimate cluster morphology, and I explore the relationship between bent radio source morphology and the surrounding cluster. By measuring the color of each galaxy and the overdensity of galaxies surrounding each AGN, I identify 39 red sequence cluster candidates, 17 of which are at redshifts of z > 1.0. Using my red sequence surface density measurement, I show that each bent AGN is not necessarily centrally located, but is generally within ~ 400 kpc of the cluster center. With this sample, I probe the dynamics of the host galaxies using the radio source morphology and find that most of the radio sources do not follow radial paths relative to the cluster center. By analyzing the morphology of the radio sources in my sample, I find that richer clusters host narrower bent sources. I also see a range of red sequence populations in the clusters, with variations, in particular, among the populations of faint red sequence galaxies. With my surface density measurements, I place preliminary constraints on cluster morphology, finding both relaxed and merging systems. Astrophysics AGN Galaxies Galaxy clusters Galaxy evolution High-redshift Radio sources
103	Structural properties of clumpy galaxies and spheroids at high redshift / Propriétés structurelles des galaxies irrégulières et des sphéroïdes dans l’univers lointain Zanella, Anita 21 September 2016 (has links) Cette thèse explore la question ouverte des mécanismes selon lesquels les galaxies lointaines évoluent au cours du temps. Elle se concentre sur l’étude des galaxies irrégulières et sur la cause de l’évolution en taille des galaxies passives et compactes. Bien que des régions de formation stellaire très lumineuses (clumps) soient observées dans les galaxies irrégulières depuis longtemps, leur nature et évolution sont encore débattues. Les instabilités gravitationnelles des disques ont été proposées comme la cause principale pour la formation in-situ des clumps, même si certains d’entre eux pourraient avoir une origine ex-situ. De plus, il n’est pas encore clair s’ils peuvent vivre longtemps ou si les vents stellaires les détruisent rapidement. À partir de l’étude détaillée d’un clump très jeune que nous avons découvert dans le disque d’une galaxie à redshift z~2 et de l’analyse d’un échantillon statistique, j’ai conclu que les clumps peuvent se former in-situ et qu’ils vivent typiquement 500 Myr. Ce résultat conforte les simulations numériques qui indiquent que les clumps ont un rôle important pour la croissance de leur noyau. Cela pourrait stabiliser le disque et y avoir un lien avec la formation des galaxies compactes et passives qui ont été decouvertes à haut redshift. Elles ont des tailles significativement plus petites, à masse égale, que celles de leurs homologues locales. Cette découverte a déclenché un débat concernant les possibles mécanismes qui peuvent augmenter leur taille sans altérer leur masse. J’ai analysé un échantillon de 32 galaxies et j’ai conclu que des multiples fusions mineures pourraient être les responsables principaux de leur evolution temporelle / This thesis explores the still unanswered question of how distant galaxies evolve through cosmic time: on one side it focuses on star-forming clumpy galaxies, on the other it investigates the size evolution of passive compact ones. Despite star forming clumps have been observed in high-redshift irregular galaxies since a while, their nature and fate are still highly debated. Violent gravitational disk instability in gas-rich, turbulent galaxies has been proposed as the main cause for in-situ clumps formation, although a fraction of them might have an ex-situ origin. Furthermore, clumps contribution to galaxy evolution is highly debated: it is not clear yet if they are long-lived or if stellar feedback rapidly disrupts them. From both the in-depth study of an extremely young clump that we discovered in the disk of a galaxy at redshift z ~ 2, and the analysis of a full statistical sample, I concluded that at least some clumps form in-situ due to violent disk instability and that they typically live ~ 500 Myr. This supports numerical simulations indicating that clumps are longlived and could play an important role in bulge growth. This might stabilize the disk, quench star formation and have therefore a link with the formation of the compact and passive galaxies that have been observed at high redshift. They have significant smaller sizes, at fixed stellar mass, than local counterparts. This discovery has ignited an important debate concerning the possible mechanisms that could inflate the galaxy sizes without altering much their mass. I analyzed a sample of 32 galaxies and I concluded that multiple minor mergers could be the main drivers of their observed time evolution Spheroïdes Galaxies passives Morphologie des galaxies Clumps Haut redshift Spheroids Passive galaxies Morphology Clumps High redshift
104	Modelling feedback processes, star formation and outflows in high-redshift galaxies / Modélisation des processus de rétro-action, de la formation stellaire et des vents dans les galaxies à haut redshift Roos, Orianne 08 September 2016 (has links) Dans l’Univers, on observe des galaxies lointaines ne formant plus d’étoiles, mais les astrophysiciens n’ont pas encore identifié avec certitude les phénomènes physiques à l’origine de leur “mort”. Pour apporter des éléments de réponse, je me suis penchée sur l’étude de phénomènes qui pourraient y jouer un rôle : les processus de rétroaction des étoiles et des trous noirs supermassifs actifs, la formation stellaire, et les vents galactiques. Le Chapitre 1 présente toutes les notions nécessaires à la compréhension du problème : les caractéristiques des galaxies typiques de l’Univers proche et lointain ; les vents galactiques ; la mort des galaxies; les trous noirs supermassifs actifs (noyaux actifs de galaxies, AGN) et les étoiles ; et leur rétroaction. Dans le Chapitre 2, je présente les techniques numériques utilisées : le code de simulations astrophysiques RAMSES et le code de transfert radiatif Cloudy, que j’ai utilisé pour développer une méthode de calcul de l’état d’ionisation d’une galaxie, détaillée au Chapitre 3. Le Chapitre 4 étudie le couplage entre les trous noirs actifs et les étoiles, avec le projet POGO, Origines Physiques des Vents Galactiques. Durant cette thèse, j’ai montré que les trous noirs actifs n’étaient pas en mesure de tuer subitement leur hôte, même en prenant en compte la rétroaction des étoiles, et que leur couplage peut réduire ou renforcer les vents dans les galaxies en fonction de leur masse. Le Chapitre 5 fait un état de l’art du domaine avant et pendant mon doctorat, reprend les conclusions de cette thèse et donne quelques perspectives, notamment en ce qui concerne le rôle additionnel des rayons cosmiques dans la mort des galaxies / In the Universe, we observe galaxies forming no, or almost no, stars anymore, but astrophysicists do not know yet what physical mechanisms cause their “death”. To give clues to solve the problem, I studied feedback processes from stars and active supermassive black holes, star formation and galactic outflows. Chapter 1 presents all the notions to understand the problem: the characteristics of typical galaxies in the local and distant Universe, galactic outflows, galaxy death, active supermassive black holes, stars, and their feedback processes. In Chapter 2, I describe the numerical techniques I used: the simulation code RAMSES, and the radiative transfer code Cloudy, which I used to develop a computation method to get the ionization state of an entire galaxy. This method is presented in Chapter 3. Chapter 4 studies the coupling between the feedback processes of active supermassive black holes and stars, with the POGO project, Physical Origins of Galactic Outflows. During this thesis, I showed that typical active supermassive black hole cannot suddenly kill their host, even when stellar feedback processes are accounted for, and that their coupling either reduces or enhances the mass outflow rate depending on the mass of the host. In Chapter 5, I give a state-of-the-art about active supermassive black holes before and during my thesis, sum up the conclusions of the work, and give perspectives to enlarge the scope of the study, especially regarding the additional role of cosmic rays in the death of galaxies Trous noirs supermassifs Vents galactiques Galaxies à haut redshift Supermassive black holes Galactic winds High-redshift galaxies
105	The Assembly of Galaxies Over Cosmic Time Guo, Yicheng 01 September 2012 (has links) To Understand how galaxies were assembled across the cosmic time remains one of the most outstanding questions in astronomy. The core of this question is how today's Hubble Sequence, namely the differentiation of galaxy morphology and its correlation to galaxy physical properties, is formed. In this thesis, we investigate the origin of the Hubble Sequence through galaxies at z~2, an epoch when the cosmic star formation activity reaches its peak and the properties of galaxies undergo dramatic transitions. Galaxies at z~2 have two important features that are distinct from nearby galaxies: much higher frequency of clumpy morphology in star-forming systems, and much compacter size. To understand the nature of the two features requires investigations on the sub-structure of galaxies in a multi-wavelength way. In this thesis, we study samples of galaxies that are selected from GOODS and HUDF, where ultra-deep and high-resolution optical and near-infrared images allow us to study the stellar populations of the sub-structures of galaxies at the rest-frame optical bands for the first time, to answer two questions: (1) the nature of kiloparsec-scale clumps in star-forming galaxies at z$\sim$2 and (2) the existence of color gradient and stellar population gradient in passively evolving galaxies at z~2, which may provide clues to the mechanisms of dramatic size evolution of this type of galaxies. We further design a set of color selection criteria to search for dusty star-forming galaxies and passively evolving galaxies at z~3 to explore the question: when today's Hubble Sequence has begun to appear. cosmology: observations galaxies: evolution galaxies: formation galaxies: high-redshift galaxies: stellar content galaxies: structure Astrophysics and Astronomy
106	Characterizing Distant Galaxies: Spectral Energy Distribution Analysis of X-ray Selected Star Forming Galaxies Johnson, Seth Pohatan 01 September 2013 (has links) Comprehensive and robust analysis of galaxies found throughout cosmic time provides the means to probe the underlying characteristics of our Universe. Coupling observations and theory, spectral energy distribution (SED) fitting provides a method to derive the intrinsic properties of distant galaxies which then aid in defining galaxy populations and constraining current galaxy formation and evolution scenarios. One such population are the sub-millimeter galaxies (SMGs) whose high infrared luminosities -- typically associated with dust-obscured star formation -- and redshift distribution places them as likely key components in galaxy evolution. To fully analyze these systems, however, requires a near complete sampling of the full SED, detailed models that encapsulate the variety of physical processes and sophisticated methods for comparing the data and models. In this dissertation, we present the general propose, Monte Carlo Markov Chain (MCMC) based SED fitting routine SED Analysis Through Markov Chains (SATMC) and the insight we have gained in modeling a sample of AzTEC 1.1mm-detected SMGs. The MCMC engine and Bayesian formalism used in the construction of SATMC offers a unique view at the constraints on model parameter space that are often grossly simplified in traditional SED fitting methods. We first present the motivation behind SATMC and its MCMC algorithm. We also highlight a series of test cases that verify not only its reliability but its versatility to various astrophysical applications, including the field of photometric redshift estimation. We then present the AzTEC SMG sample and preliminary results obtained through counterpart identification, X-ray spectral modeling and SED fitting with SATMC. Finally, we present the latest work in detailed SED analysis of SMGs and how these results influence our understanding of the SMG population. galaxies - fundamental parameters Galaxies - high redshift Galaxies - submillimeter methods - statistical Astrophysics and Astronomy
107	IDENTIFYING PROTOCLUSTERS IN THE HIGH REDSHIFT UNIVERSE AND MAPPING THEIR EVOLUTION Franck, Jay 01 February 2018 (has links) No description available. Astronomy Astrophysics
108	Obscuration, environments and host galaxies of active galactic nuclei Mayo, Jack Henry January 2014 (has links) The work contained within this thesis Is made up primarily of two pieces Both address active galactic nuclei And the galaxies that live nearby The obscured fraction of the population Is the topic of one publication And the type-II fraction in the optical regime In chapter four this is the theme I research the vicinity overdensity Around radio galaxies in chapter three, you’ll see I reduce some spectra at redshift one But not all observations in the end got done With the spectra I have I do what I can As if all target observations had actually ran In the end I conclude with results and the theme of research to be done further downstream. The works contained herein addresses two major topics in extragalactic astrophysics, namely the Type-II AGN fraction and the Overdensity-Radio power relation. Quantifying the Type-II AGN fraction has been attempted by many works in many different observational regimes, finding rather contrasting results. Accretion onto supermassive black holes contributes between 5 per cent and 20 per cent of the luminosity of the Universe, and seems to be closely linked to star formation processes. The large uncertainty on this value is due to the ill-determined contribution from obscured accretion, namely the Type-II fraction. In Chapters 3 and 4 I address this issue from a theoretical standpoint in the X-ray regime and an observational standpoint in the optical regime respectively. In Chapter 3 I show how crude X-ray spectroscopy of partially obscured AGN can lead to catastrophic underestimations of the intrinsic X-ray luminosity of these sources. Acting over an entire population, these partial obscurers can produce an obscured AGN fraction which decreases as a function of observed luminosity. The results are consistent with observations in the X-ray vs. IR luminosity of AGN classes. In Chapter 4 I select a statistically significant sample of AGN from an unbiased 250μm galaxy sample. After spectroscopic classification I find the optical Type- II AGN fraction to be consistent across several decades in [OIII] luminosity, a common proxy for intrinsic AGN luminosity. I also investigate the relation of AGN activity to host galaxy mass, as well as star formation activity and star formation history. Probing the environments of protoclusters will help to constrain the models of structure formation in the Universe. Until now, no dataset has been big enough to probe the environments of high redshift radio galaxies at a statistical level; While many believe that the feedback processes of high luminosity radio jets will have a direct impact on star formation in the surrounding medium it has not been tested. In Chapter 2 I investigate this on an statistical level, finding no meaningful correlation between radio galaxy radio power and source overdensity in the vicinities of these sources. In Chapter 5 I discuss the reduction of a 24μm sample at redshift z ∼ 1 for direct comparison with a local 12μm sample. With only a fraction of the target sample being observed, no statistically significant results could be derived, but the objects are spectroscopically classified and spectroscopic redshifts are measured where possible. Correlations in the data set are investigated and the limitations of the sample selection strategy are discussed. 523.01
109	Star-formation history of the universe and its drivers Sobral, David Ricardo Serrano January 2011 (has links) Determining the cosmic star formation history of the Universe is fundamental for our understanding of galaxy formation and evolution. While surveys now suggest that the "epoch" of galaxy formation occurred more than 6 billion years ago, our measurements still suff er from signi ficant scatter and uncertainties due to the use of diff erent indicators, dust extinction and the e ffects of cosmic variance in the current samples. Furthermore, understanding galaxy formation and evolution require us to go much beyond simply determining the star formation history of the Universe with high accuracy: what are the physical mechanisms driving the strong evolution that we observe? How does star formation depend on stellar mass and environment and how does that change with cosmic time? This thesis presents both a completely self-consistent determination of the star formation history of the Universe (based on a single, sensitive and well-calibrated star formation indicator up to redshift z ~ 2:3: the H α luminosity) and investigates its drivers by exploring large area surveys (probing a range of environments and overcoming cosmic variance) obtained with the High-redshift Emission Line Survey (HiZELS). HiZELS is a panoramic extragalactic survey using the WFCAM instrument on the 3.8-m UK Infrared Telescope (UKIRT) which utilizes a set of existing and custom-made narrow-band filters in the J, H and K bands to detect emission line galaxies (main targets are H α emitters at z = 0:84, z = 1:47 and z = 2:23) up to z ~ 9 over square degree areas of extragalactic sky. Detailed measurements of the H α luminosity function and its evolution with redshift are presented, revealing a signi ficant luminosity evolution. The clustering properties of H α emitters at high-redshift are quantifi ed and investigated for the first time, revealing that these distant galaxies reside in Milky-Way type dark matter haloes at z ~ 1. Mass and environment are found to have important and inter-dependent roles on star formation at high-z and the results are able to reconcile previously contradictory results in the literature. Furthermore, by conducting a novel double-narrow band survey at z = 1:47, the relationship between the [Oii]3727 and H α emission lines is studied in detail and directly compared to z ~ 0, showing no signifi cant evolution in the dust properties of star-forming galaxies, despite the very strong luminosity evolution. Finally, this thesis also presents the widest search for very distant Ly α emitters at z ~ 9. 520
110	Massive galaxies at high redshift Pearce, Henry James January 2012 (has links) A unique K-band selected high-redshift spectroscopic dataset (UDSz) is exploited to gain further understanding of galaxy evolution at z > 1. Acquired as part of an ESO Large Programme, this thesis presents the reduction and analysis of a sample of ∼ 450 deep optical spectra of a random 1 in 6 sample of the KAB < 23, z > 1 galaxy population. Based on the final reduced dataset, spectrophotometric modelling of the optical spectra and multi-wavelength photometry available for each galaxy is performed using a combination of single and dual component stellar population models. The stellarmass and age estimates provided by the spectrophotometric modelling are exploited throughout the rest of the thesis to investigate the evolution of massive galaxies at z > 1. Focusing on a K-band bright (K < 21.5) sub-sample in the redshift range 1.3 < z < 1.5 the galaxy size-mass relation has been studied in detailed. In agreement with some previous studies it is found that massive, old, early-type galaxies (ETGs) have characteristic radii a factor ~- 1.5 − 3.0 smaller than their local counterparts at a given stellar-mass. Due to the potential errors in spectrophotometric estimates of the stellarmasses at high redshift velocity dispersion measurements are derived for a sub-sample of massive ETGs at z > 1.3 in order to calculate dynamical mass estimates. To date, only a handful of objects at z > 1.3 have individual velocity dispersion estimates in the literature. Here the largest single sample (13 objects) of velocity dispersion measurements at high redshift is presented. The results for the sub-sample of objects with dynamical mass estimates confirm the results based on stellar mass estimates that high redshift massive systems are more compact than their local counterparts. The fraction of K-band bright objects at high redshift that are passively evolving is calculated with specific star-formation rates from the UV rest-frame continuum, [OII] emission and 24μm data. It is concluded that ∼ 58 ± 10% of the K < 21.5, 1.3 < z < 1.5 galaxy population is passively evolving. Various photometric techniques for separating star-forming and passively evolving galaxies are assessed by exploiting the accurate spectral types derived for the UDSz spectroscopic sample. Popular highredshift selection techniques are shown to fail to effectively select complete samples of passive objects with low levels of contamination. Using detailed information available for the UDSz dataset, various techniques are optimised and then used to estimate the passive fraction from the full UDS photometric catalog. The passive fraction results from the full photometric catalog are found to agree well with the results derived from the UDSz sample. With the Visible and Infrared Survey Telescope for Astronomy (VISTA) now starting to produce data, the opportunity has been taken to develop high-redshift galaxy population dividers based on the VISTA filters. Using the first data release from the VISTA Deep Extragalactic Observations (VIDEO) survey (VVDS D1 field), the passive fractions of K-band limited samples have been estimated to compare with results derived in the UDS. Within the errors the passive fraction estimates in the UDS and VISTA VVDS D1 field are found to agree reasonably well. Finally, composite spectra are used to study the evolution of various different galaxy sub-samples as a function of redshift, age, stellar-mass and specific star-formation rate. This work produces an remarkably clean result, showing that the massive, absolute Kband bright, passively evolving ETGs are always the oldest population, with ages close to the age of the Universe at z ∼ 1.4. In contrast, the late-type, low-mass, star-forming galaxies are always found to be much younger systems. This result strongly supports the downsizing scenario, in which more massive systems complete their stellar-mass assembly before lower-mass counterparts. 520

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