Global ETD Search

41	Scaling relations and stellar populations of galaxy clusters from their first epochs of assembly to the present / Relations d'échelle et populations stellaires dans les amas de galaxies de leurs premières époques d'assemblage au présent Amodeo, Stefania 20 September 2018 (has links) Cette thèse porte sur le rôle des amas de galaxies dans la cosmologie et l'évolution des galaxies. J'utilise des observations photométriques et spectroscopiques multi-longueur d'onde (optiques, mm, proche/moyen-IR) que j'analyse avec des méthodes statistiques. Pour un échantillon d'amas détectés par le satellite Planck et ré-observés avec le télescope optique Gemini, j'étudie la dynamique des galaxies dans les amas afin de déterminer leur masse et de comprendre les erreurs systématiques sur ces estimations, d'une importance cruciale dans la cosmologie à l'heure actuelle. Dans le cadre de la collaboration CARLA (Clusters Around Radio Loud AGN), j’étudie les populations stellaires des galaxies dans les amas et les proto-amas dans leurs premières phases d'assemblage (z>1.4), afin d'étudier la suppression de la formation des étoiles et le rôle de l'environnement sur l'évolution des galaxies. / This thesis focuses on the role of galaxy clusters in cosmology and galaxy evolution. I use multi-wavelenght photometric and spectroscopic observations (optical, mm, near/mid- IR) which I analyse with statistical methods. For a sample of clusters detected by the Planck satellite and re-observed with the Gemini optical telescope, I have studied the dynamics of member galaxies to probe their mass and understand possible systematics affecting such estimates, of crucial importance in cluster cosmology at present. Within the CARLA (Clusters Around Radio Loud AGN) collaboration, I examine morphology and stellar populations of galaxies in clusters and proto-clusters in their first assembly phases (z>1.4), with the aim of shedding light on the quenching of star formation and the role of the environment on galaxy evolution. Galaxies Amas de galaxies Observations Evolution de galaxies Galaxies Galaxy clusters Observations Galaxy evolution 520
42	Tomografia do potencial gravitacional primordial através da polarização da radiação cósmica de fundo em aglomerados de galáxias / Tomography of the primordial gravitational potential using cosmic microwave background polarization in galaxy clusters Xavier, Henrique Scemes 26 November 2007 (has links) Após uma revisão das bases da cosmologia moderna e dos mecanismos de produção de anisotropias na radiação cósmica de fundo, calculamos a relação entre a polarização da radiação cósmica de fundo causada por espalhamento Thomson no gás ionizado presente em aglomerados de galáxias e o potencial gravitacional da época do desacoplamento dos fótons com a matéria, em z \' 1100. Mostramos como é possível realizar, em teoria, uma tomografia desse potencial gravitacional em todo o universo observável e como a correlação desse sinal de polarização com o contraste de densidade de matéria poderia nos ajudar a restringir parâmetros cosmológicos. Entretanto, o fraco sinal esperado para essa polarização nos leva à conclusão de que uma tomografia do potencial gravitacional, através desse método, é impraticável no futuro próximo. / After a review of the foundations of modern cosmology and the cosmic microwave background anisotropies production mechanisms, we calculated the relation between the cosmic microwave background polarization caused by Thomson scattering in the ionized gas found in galaxy clusters and the gravitational potential from the photon decoupling epoch, on z \' 1100. We have shown how it is possible to make, in theory, a tomography of this potential over all the observable universe and how the correlation of this polarization signal with the matter density contrast could help us constrain cosmological parameters. However, the weak signal expected for this polarization shows that a gravitational potential tomography using this method is unfeasible in the near future. Aglomerados de galáxias Cosmic microwave background Cosmologia Cosmology Galaxy clusters Polarização Polarization Radiação cósmica de fundo Tomografia Tomography
43	Origem e evolução dos campos magnéticos cosmológicos / The Origin and Evolution of Cosmic Magnetic Fields Rafael da Silva de Souza 26 June 2009 (has links) Campos magnéticos de intensidade $\\sim \\mu$G são observados tanto em nossa galáxia, quanto em galáxias com alto desvio para o vermelho (\\emph{z}), onde o dínamo $\\alpha-\\Omega$ não deveria ter tempo para produzi-lo. Por conseguinte, uma origem primordial é indicada. Foi proposto que os campos primordiais surgiram em várias eras: durante a inflação, na transição de fase eletrofraca, na transição de fase quark hádron (TFQH), durante a formação dos primeiros objetos e durante a reionização. Nós sugerimos aqui, que estes campos magnéticos observados em galáxias através de medidas de rotação Faraday, têm sua origem em flutuações eletromagnéticas que naturalmente ocorreram no plasma quente e denso, existente logo após a TFQH. Nós evoluímos os campos previstos por nosso modelo até a época atual. O tamanho da região de coerência do campo magnético aumenta devido à fusão de regiões menores. Campos magnéticos de $\\sim 10 \\mu$G sobre regiões comóveis de $\\sim 1$ pc foram encontrados para \\emph{z} $\\sim 10$. Investigamos a amplificação destes campos sementes pelo dínamo turbulento em protogaláxias. A taxa de amplificação devido à um vórtice turbulento de raio $L$ com velocidade circular $V$ é da ordem de $V/L$. Enquanto o modelo padrão de dínamo tem um tempo de amplificação para um disco galáctico típico de $\\sim 10^{9}$ anos, o dínamo turbulento de pequena escala tem uma taxa de amplificação de $\\sim 10^{7}$ anos. Usamos as equações não-lineares para evolução da correlação magnética de forma a avaliar a evolução da amplificação destes campos na protogaláxia. Vários autores sugeriram uma origem gravitacional para os campos magnéticos em objetos celestes em rotação. Isto foi motivado em parte pela conjectura Schuster-Blackett (S-B), onde se propõe que os campos magnéticos em planetas e estrelas surgem devido à sua rotação. Neste cenário, correntes de massa neutra geram campos magnéticos, implicando na existência de um acoplamento entre os campos gravitacional e magnético. Nós também investigamos a possibilidade da conjectura S-B ser a origem dos intensos campos magnéticos em magnetares e \\emph{gamma ray bursts}. Além disso, estudamos a influência da pressões não térmicas, na determinação da massa de aglomerados de galáxias, usando dados públicos do XMM-Newton para 5 aglomerados de Abell. A pressão não térmica considerada aqui, é composta pelas componentes magnética e turbulenta. Nós consideramos estas duas componentes na equação do equilíbrio hidrostático e comparamos as estimativas de massa total, com os valores obtidos sem estas componentes. / Magnetic fields of intensities $\\sim \\mu$G are observed both in our galaxy and in high redshift (\\emph{z}) galaxies, where a mean field dynamo would not had time to produce them. Therefore, a primordial origin is indicated. It has been suggested that magnetic fields were created at various primordial eras: during inflation, the electroweak phase transition, the quark-hadron phase transition (QHPT), during the formation of the first objects, and during reionization. We suggest here that the magnetic fields observed in galaxies by Faraday Rotation Measurements (FRMs), have their origin in the electromagnetic fluctuations that naturally occurred in the dense hot plasma that existed just after the QHPT. We evolve the predicted fields to the present time. The size of the region containing a coherent magnetic field increased due to the fusion of smaller regions. Magnetic fields (MFs) $\\sim 10 \\mu$G over a comoving $\\sim 1$ pc region are predicted at redshift \\emph{z} $\\sim 10$. The amplification of these seed fields by the turbulent dynamo in a protogalaxy is here investigated. The e-fold amplification time by a turbulent eddy of radius $L$ with a circular velocity $V$ is on the order of $L/V$. Whereas the standard dynamo for a typical disk galaxy has an e-fold amplification time $\\sim 10^{9}$ years, the small scale turbulent dynamo has an e-fold time $\\sim 10^{7}$ years. We use the non-linear evolution equations for the magnetic correlations in order to analyze the amplifications of these fields in protogalaxies. Various authors have suggested a gravitational origin of the magnetic fields in rotating celestial bodies. It has been motivated, in part, by the Schuster-Blackett (S-B) conjecture, which suggests that the magnetic fields in planets and stars arise due to their rotation. In this scenario, neutral mass currents generate magnetic fields, implying the existence of a coupling between gravitational and electromagnetic fields. In this work, we investigate the possibility that the S-B conjecture is the origin of the intense magnetic fields near rotating compact objects, in particular connected with magnetars and gamma ray bursts. We also studied the influence of non-thermal pressure on the cluster mass determination using public XMM-Newton archival data for 5 Abell clusters. The non-thermal pressure considered here, is composed of the magnetic and the turbulent components. We also take into account these two non-thermal components in the hydrostatic equilibrium equation, and we compare the total mass estimated with the values obtained without assuming them. Aglomerados de Galáxias Campos Magnéticos Cosmologia Plasmas Turbulência Cosmology Galaxy Clusters Magnetic Fields Plasmas Turbulence
44	Gamma-Ray Emission from Galaxy Clusters : DARK MATTER AND COSMIC-RAYS Pinzke, Anders January 2010 (has links) The quest for the first detection of a galaxy cluster in the high energy gamma-ray regime is ongoing, and even though clusters are observed in several other wave-bands, there is still no firm detection in gamma-rays. To complement the observational efforts we estimate the gamma-ray contributions from both annihilating dark matter and cosmic-ray (CR) proton as well as CR electron induced emission. Using high-resolution simulations of galaxy clusters, we find a universal concave shaped CR proton spectrum independent of the simulated galaxy cluster. Specifically, the gamma-ray spectra from decaying neutral pions, which are produced by CR protons, dominate the cluster emission. Furthermore, based on our derived flux and luminosity functions, we identify the galaxy clusters with the brightest galaxy clusters in gamma-rays. While this emission is challenging to detect using the Fermi satellite, major observations with Cherenkov telescopes in the near future may put important constraints on the CR physics in clusters. To extend these predictions, we use a dark matter model that fits the recent electron and positron data from Fermi, PAMELA, and H.E.S.S. with remarkable precision, and make predictions about the expected gamma-ray flux from nearby clusters. In order to remain consistent with the EGRET upper limit on the gamma-ray emission from Virgo, we constrain the minimum mass of substructures for cold dark matter halos. In addition, we find comparable levels of gamma-ray emission from CR interactions and dark matter annihilations without Sommerfeld enhancement. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Accepted. Galaxy clusters gamma-rays cosmic-rays dark matter High energy astrophysics Högenergiastrofysik
45	Modeling Spatially and Spectrally Resolved Observations to Diagnose the Formation of Elliptical Galaxies Snyder, Gregory Frantz 30 September 2013 (has links) In extragalactic astronomy, a central challenge is that we cannot directly watch what happens to galaxies before and after they are observed. This dissertation focuses on linking predictions of galaxy time-evolution directly with observations, evaluating how interactions, mergers, and other processes affect the appearance of elliptical galaxies. The primary approach is to combine hydrodynamical simulations of galaxy formation, including all major components, with dust radiative transfer to predict their observational signatures. The current paradigm implies that a quiescent elliptical emerges following a formative starburst event. These trigger accretion onto the central supermassive black hole (SMBH), which then radiates as an active galactic nucleus (AGN). However, it is not clear the extent to which SMBH growth is fueled by these events nor how important is their energy input at setting the appearance of the remnant. This thesis presents results drawing from three phases in the formation of a typical elliptical: 1) I evaluate how to disentangle AGN from star formation signatures in mid-infrared spectra during a dust-enshrouded starburst, making testable predictions for robustly tracing SMBH growth with the James Webb Space Telescope ; 2) I develop a model for the rate of merger-induced post-starburst galaxies selected from optical spectra, resolving tension between their observed rarity and merger rates from other estimates; and 3) I present results from Hubble Space Telescope imaging of elliptical galaxies in galaxy clusters at 1 < z < 2, the precursors of present-day massive clusters with $M \sim10^{15}M_{\odot}$, demonstrating that their stars formed over an extended period and ruling out the simplest model for their formation history. These results lend support to a stochastic formation history for ellipticals driven by mergers or interactions. However, significant uncertainties remain in how to evaluate the implications of galaxy appearance, in particular their morphologies across cosmic time. In the final chapter, I outline an approach to build a "mock observatory" from cosmological hydrodynamical simulations, with which observations of all types, including at high spatial and spectral resolutions, can be brought to bear in directly constraining the physics of galaxy formation and evolution. / Astronomy Astronomy Astrophysics Cosmology Galaxy Clusters Galaxy Evolution Galaxy Formation Radiative Transfer Supermassive Black Holes
46	THE INTERACTION BETWEEN THE INTRACLUSTER MEDIUM AND THE CLUSTER STELLAR CONTENT Sivanandam, Suresh January 2010 (has links) We study specific aspects of the relationship between the stellar content and the intracluster media (ICM) of galaxy clusters. First, we attempt to solve the long-standing difficulty in explaining the highly enriched ICM by including a previously unaccounted for stellar component: the intracluster stars. To determine the relative contributions of galactic and intracluster stars to the enrichment of the intracluster medium (ICM), we present X-ray surface brightness, temperature, and Fe abundance profiles for a set of twelve galaxy clusters for which we have extensive optical photometry. Assuming a standard IMF and simple chemical evolution model scaled to match the present-day cluster early-type SN Ia rate, the stars in the brightest cluster galaxy (BCG) plus the intracluster stars (ICS) generate 31⁺¹¹₋₉%, on average, of the observed ICM Fe within r₅₀₀(∼ 0.6 times r₂₀₀, the virial radius). Because the ICS typically contribute 80% of the BCG+ICS Fe, we conclude that the ICS are significant, yet often neglected, contributors to the ICM Fe within r₅₀₀. However, the BCG+ICS fall short of producing all the Fe, so metal loss from stars in other cluster galaxies must also contribute. By combining the enrichment from intracluster and galactic stars, we can account for all the observed Fe. These models require a galactic metal loss fraction (0.84(−0.14)^(+0.11)) that, while large, is consistent with theoretical models of Fe mass not retained by galactic stars. The SN Ia rates, especially as a function of galaxy environment and redshift, remain a significant source of uncertainty in further constraining the metal loss fraction. Second, we study the effects of ram-pressure stripping on infalling galaxies using a warm molecular hydrogen (H₂) as a tracer by carrying out a Spitzer infrared spectrograph (IRS) survey of four galaxies with signatures of ram-pressure stripping. We have discovered two galaxies, ESO 137-001 and NGC 4522, with warm H₂ tails stretching 20 kpc and 4 kpc in length, respectively. In the case of ESO 137-001 where we measure a warm H₂ mass loss rate of ∼ 2 − 3 M⊙ yr⁻¹, we estimate that the galaxy will lose all of its gas in a single pass through the cluster core. Strong warm H₂ emission is detected in one other galaxy, CGCG 97-073, which a region within its tail that is mainly dominated by H₂ emission. The warm H₂ observed in these three galaxies share similar temperature and column density properties with warm H₂ masses ranging from 10⁶ − 10⁸ M⊙. From a comparison with the SINGS warm H₂ sample, our results indicate that these galaxies experiencing significant ram-pressure stripping show anomalously high warm H₂ emission that cannot be explained purely from star formation. This adds credence to the hypothesis that H₂ within these galaxies is being shock-heated from the interaction with the ICM. We also discover that stripping of warm and hot dust, as measured at 8 μm and 24 μm, is a common feature of the galaxies observed in our sample. In the case of NGC 4522, we capture the turbulent nature of the stripping process. We measure the star formation rates using published Hα and measured 24 μm luminosities for all of our galaxies and find that some of them have suppressed star formation rates compared to similar mass counterparts in the field. We find a possible association between Hα and warm H₂ emission in three of the four galaxies observed. We conclude that the variation of H₂ properties observed in our sample is likely due to the galaxies being in different stages of ram-pressure stripping. Finally, we report on our efforts to improve the performance of the Lochkeed Arizona Infrared Spectrometer (LAIRS), a near-IR, tunable filter imager. We have made significant progress in identifying the sources of key issues such as the a highly asymmetric line profile and the unstable performance of the servo controller at the MMT. Solutions have been implemented for these issues, such as a revised mounting strategy for the tunable filter plates and a completely new controller with higher bandwidth. Significant progress has been made towards resolving these issues, but a few issues remain before LAIRS meets all of its requirements. Enrichment Galaxy Clusters Intracluster Medium IR Instrumentation Ram-pressure Stripping Tunable filters
47	The Stellar Populations and Evolution of Virgo Cluster Galaxies Roediger, Joel C. 25 August 2009 (has links) Using a combination of optical and near-infrared photometry, we have studied both the resolved and integrated stellar populations for a sample of Virgo cluster galaxies spanning the full range of galaxian parameters. The derived stellar population properties are compared against galaxy structural and environmental measures to gauge the importance of these factors in establishing galaxy star formation histories and chemical evolution. Although galaxy colours do not uniquely probe a galaxy's star formation history, meaningful results may be obtained if considered in a relative sense. We find that colour profiles reflect variations in both stellar age and metallicity within galaxies. We also uncover systematic variations in colour gradients, and thus age/metallicity gradients, along the Hubble sequence, such that age and metallicity gradients become increasingly negative toward later Hubble types. However, only weak correlations exist between galaxies' stellar populations and their structure and environment. The correlations we find suggest that the star formation histories of gas-rich galaxies are strongly influenced by gas removal within the cluster, while their chemical evolution is due to a combination of stellar mass-dependent enrichment and outflow retention. The assembly of gas-poor giant galaxies is consistent with a hierarchical scenario wherein gas-rich mergers dominate by number. Gas-poor dwarfs differ from the giants, however, appearing as the product of environmentally-driven evolution. Spiral galaxies bridge the dwarf-giant gap, whereby merging and gas-stripping signatures are imprinted in their stars. Early-type spirals seem to have fallen into the cluster sooner than the later types, thereby ceasing star formation in their disks at earlier epochs. The bulges of both types, however, appear to have grown via merging. The nature of this merging (minor versus major) remains unknown. Irregular galaxies exhibit signs of a recent gravitational encounter that has redistributed both their stars and gas, the latter of which caused recent star formation. / Thesis (Master, Physics, Engineering Physics and Astronomy) -- Queen's University, 2009-08-25 14:12:46.48 Extragalactic Astronomy Galaxy Evolution Stellar Content Star Formation Histories Chemical Evolution Galaxy Clusters
48	The Stellar Content in Clusters of Galaxies Bildfell, Christopher John 26 April 2013 (has links) We investigate three separate topics associated with the formation and evolution of the stellar mass component in galaxy clusters. The work presented herein is based primarily on optical imaging and spectra taken with, respectively, the Canada-France-Hawaii Telescope and Gemini North/South. We confront the result from the optical data analysis with the results from the analysis of high-resolution X-ray data taken with the Chandra and XMM-Newton space observatories. Confirming earlier results, we find that 22% of brightest cluster galaxies (BCGs) show central inversions in their optical color profiles (blue-cores), indicative of recent star formation or AGN activity. Based on the extended sizes of the blue-core regions we favour recent star formation. Comparison with the host cluster central entropies (and other X-ray properties) demonstrates that the source of cold gas required to fuel the recent activity in BCG cores is direct condensation from the rapidly cooling intra-cluster medium. We measure the giant-to-dwarf ratio (GDR) of red sequence galaxies in a sample of 97 clusters to constrain its evolution over the redshift range 0.05 < z < 0.55. We find that the GDR is evolving and can be parameterized by GDR=(0.88 +/- 0.15)z+(0.44 +/- 0.03). We find that the intrinsic scatter in this relation is consistent with zero, after accounting for measurement error, Poisson noise and contributions from large-scale structure. After correcting for cluster mass effects we investigate the evolution of the individual dwarf and giant populations in order to probe the source of the observed GDR evolution. Beyond z=0.25 the GDR evolution is driven by an increase in the number of dwarfs (consistent with interpretations from the literature), however, below z=0.2 the GDR evolution is caused by a significant reduction in the number of giants. We interpret this a evidence for a significant number of major mergers in the giant population at late times. This is supported by the relatively short dynamical friction timescales for these galaxies. We use velocity-broadened stellar template models to fit the optical spectra of 19 BCGs in order to measure their the line-of-sight component of their central velocity dispersions (sigma). The sigma values are combined with previous measurements of effective radii re and effective surface brightness <I>e to investigate the properties of the BCG fundamental plane. We measure a BCG fundamental plane parameterized by log( re )= alpha log( sigma ) + beta log( <I>e ) + gamma, with best fit parameters alpha = 1.24 +/- 0.08, beta = -0.80 +/- 0.1 and gamma = (0.3 +/- 2.0)x10-4. We constrain the intrinsic scatter in this relation to be deltaint = 0.066 +/- 0.010 in re, consistent with previous measures of the scatter in the fundamental plane for regular cluster ellipticals. Comparing the slope parameters (alpha, beta) of the BCG FP to those from previous studies of the FP for regular cluster ellipticals, we find that there is no conclusive evidence for curvature in the unified FP. We use the sigma measurements to estimate the BCG dynamical masses Mdyn. Comparing these estimates with mass proxies for the clusters (Tx, ng) we find that BCG mass is independent of cluster mass with Mdyn = (2.9 +/- 1.8)x1012 solar masses. / Graduate / 0606 / 0605 / bildfell@uvic.ca Astronomy Astrophysics Galaxy Clusters Brightest Cluster Galaxies Stars Active Galactic Nuclei Star Formation Feedback
49	Astrophysical signatures of axion-like particles Day, Francesca January 2017 (has links) The Standard Model of particle physics has enjoyed unprecedented success in predicting experimental results. However, evidence from astrophysical observations points to the existence of a dark sector of particles that interact only very weakly with the Standard Model. In this work, we search for dark sector signatures in X-ray telescope data. Much of this work concerns a class of hypothetical particles, the axion-like particle (ALP). ALPs are a theoretically well-motivated extension of the Standard Model. If ALPs exist, they may lead to intriguing astrophysical signatures: in the presence of a background magnetic field, ALPs and photons can interconvert. We could detect ALPs by searching for photon to ALP conversion. For example, photons produced by point sources in or behind galaxy clusters may convert to ALPs in the cluster's magnetic field. This could lead to observable spectral anomalies. Using this strategy, we place world leading bounds on the ALP-photon coupling. One potential signal of dark matter is an anomalous line in the spectra of galaxies and galaxy clusters. In 2014, an anomalous line was found at an energy of 3.5 keV. The nature and cause of this line is still under discussion. We analyse a scenario in which the 3.5 keV line arises from dark matter decay to ALPs, which interconvert with 3.5 keV photons in astrophysical magnetic fields. We further report an anomalous deficit at 3.5 keV in the spectrum of the Active Galactic Nucleus at the centre of the Perseus galaxy cluster. This motivates the study of a new model in which both features are caused by âfluorescent dark matterâ which resonantly interacts with 3.5 keV photons. We analyse observations of Perseus at 3.5 keV to date, and show that they are well explained by this model. Further theoretical and experimental work is needed to discover or exclude fundamental physics effects in X-ray spectra.
50	Etude des amas de galaxies avec l'expérience PLANCK, via l'effet Sunyaev-Zel'dovich / The Sunyaev-Zel'dovich effect from galaxy clusters with the PLANCK satellite Hurier, Guillaume 10 December 2012 (has links) Cette thèse se focalise sur l'étude des amas de galaxies, via l'effet Sunyaev-Zel'dovich (tSZ), qui consiste en l'interaction de ces même amas avec le fond diffus cosmologique. Pour ce faire j'ai utilisé les données expérimentale de l'instrument HFI du satellite PLANCK. Cette thèse ce découpe en trois parties majeures, (1) L'analyse et le traitement des données en temps, des données brut jusqu'au cartes du ciel, ce focalisant tout particulièrement sur les effets systématiques. (2) Le développement de méthode de séparation de sources, permettant la construction de cartes par émission astrophysique (tout particulièrement l'effet Sunyaev-Zel-dovich) à partir de données multi-fréquences. (3) L'analyse physique des cartes d'effet Sunyaev-Zel'dovich, produit par le gaz d'électron chaud présent dans les amas de galaxies. Ce travail permet la mise en place de contrainte, sur le profile de pression des amas de galaxies, sur la présence de filaments de matière entre des système binaire d'amas de galaxies, ainsi que la mise en évidence du spectre de puissance de l'effet tSZ. / This work is focusing on the study of the thermal Sunyaev-Zel'dovich (tSZ) effect produced by the gaz of hot electrons present in galaxy clusters. This effect consist on the interaction between the Cosmic Microwave Background (CMB) and galaxiy clusters. For this purpuse I used the data from the High Frequency Instrument (HFI) of the PLANCK satellite. This work can be divided in three main parts : (1) The study of systématics effects present in the Time Ordered Data and in the construction of the sky maps. (2) The devellopement of new components seperation methods for the tSZ effect in the context of multi-frequencies observations. (3) The physical analysis of the tSZ effect providing constraints on the galaxy clusters properties. This work allow to put some constraints on the galaxy clusters pressure profile, on the WHIM components present in the inter-clusters medium between binary system of galaxy clusters and on the detection of the tSZ power spectrum with PLANCK. Sunyaev-Zel'dovich PLANCK CMB Amas de galaxies Cosmologie Sunyaev-Zel'dovich PLANCK CMB Galaxy clusters Cosmology 530

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