Your search keyword '"Maurilio Pannella"' showing total 4 results

1. Revealing the Environmental Dependence of Molecular Gas Content in a Distant X-Ray Cluster at z = 2.51.

Author

Tao Wang, David Elbaz, Emanuele Daddi, Daizhong Liu, Tadayuki Kodama, Ichi Tanaka, Corentin Schreiber, Anita Zanella, Francesco Valentino, Mark Sargent, Kotaro Kohno, Mengyuan Xiao, Maurilio Pannella, Laure Ciesla, Raphael Gobat, and Yusei Koyama

Published

2018

2. “Super-deblended” Dust Emission in Galaxies. I. The GOODS-North Catalog and the Cosmic Star Formation Rate Density out to Redshift 6.

Author

Daizhong Liu, Emanuele Daddi, Mark Dickinson, Frazer Owen, Maurilio Pannella, Mark Sargent, Matthieu Béthermin, Georgios Magdis, Yu Gao, Xinwen Shu, Tao Wang, Shuowen Jin, and Hanae Inami

Subjects

GALAXY clusters, COSMIC dust, STAR formation, REDSHIFT, PARAMETER estimation

Abstract

We present a new technique to measure multi-wavelength “super-deblended” photometry from highly confused images, which we apply to Herschel and ground-based far-infrared (FIR) and (sub-)millimeter (mm) data in the northern field of the Great Observatories Origins Deep Survey. There are two key novelties. First, starting with a large database of deep Spitzer 24 μm and VLA 20 cm detections that are used to define prior positions for fitting the FIR/submm data, we perform an active selection of useful priors independently at each frequency band, moving from less to more confused bands. Exploiting knowledge of redshift and all available photometry, we identify hopelessly faint priors that we remove from the fitting pool. This approach significantly reduces blending degeneracies and allows reliable photometry to be obtained for galaxies in FIR+mm bands. Second, we obtain well-behaved, nearly Gaussian flux density uncertainties, individually tailored to all fitted priors for each band. This is done by exploiting extensive simulations that allow us to calibrate the conversion of formal fitting uncertainties to realistic uncertainties, depending on directly measurable quantities. We achieve deeper detection limits with high fidelity measurements and uncertainties at FIR+mm bands. As an illustration of the utility of these measurements, we identify 70 galaxies with and reliable FIR+mm detections. We present new constraints on the cosmic star formation rate density at , finding a significant contribution from dusty galaxies that are missed by optical-to-near-infrared color selection. Photometric measurements for 3306 priors, including more than 1000 FIR+mm detections, are released publicly with our catalog. [ABSTRACT FROM AUTHOR]

Published

2018

3. A GIANT LYα NEBULA IN THE CORE OF AN X-RAY CLUSTER AT Z = 1.99: IMPLICATIONS FOR EARLY ENERGY INJECTION.

Author

Francesco Valentino, Emanuele Daddi, Alexis Finoguenov, Veronica Strazzullo, Amandine Le Brun, Cristian Vignali, Frédéric Bournaud, Mark Dickinson, Alvio Renzini, Matthieu Béthermin, Anita Zanella, Raphaël Gobat, Andrea Cimatti, David Elbaz, Masato Onodera, Maurilio Pannella, Mark Sargent, Nobuo Arimoto, Marcella Carollo, and Jean-Luc Starck

Subjects

ACTIVE galaxies, GALAXY clusters, NEBULAE, GALACTIC redshift, STELLAR evolution, GALACTIC evolution

Abstract

We present the discovery of a giant ≳100 kpc Lyα nebula detected in the core of the X-ray emitting cluster CL J1449+0856 at z = 1.99 through Keck/LRIS narrow-band imaging. This detection extends the known relation between Lyα nebulae and overdense regions of the universe to the dense core of a 5–7 × 1013M⊙ cluster. The most plausible candidates to power the nebula are two Chandra-detected AGN host cluster members, while cooling from the X-ray phase and cosmological cold flows are disfavored primarily because of the high Lyα to X-ray luminosity ratio (, ≳10–1000 times higher than in local cool-core clusters) and by current modeling. Given the physical conditions of the Lyα-emitting gas and the possible interplay with the X-ray phase, we argue that the Lyα nebula would be short-lived (≲10 Myr) if not continuously replenished with cold gas at a rate of ≳1000 M⊙ yr−1. We investigate the possibility that cluster galaxies supply the required gas through outflows and we show that their total mass outflow rate matches the replenishment necessary to sustain the nebula. This scenario directly implies the extraction of energy from galaxies and its deposition in the surrounding intracluster medium (ICM), as required to explain the thermodynamic properties of local clusters. We estimate an energy injection of the order of per particle in the ICM over a 2 Gyr interval. In our baseline calculation, AGNs provide up to 85% of the injected energy and two-thirds of the mass, while the rest is supplied by supernovae-driven winds. [ABSTRACT FROM AUTHOR]

Published

2016

4. DISCOVERY OF A GALAXY CLUSTER WITH A VIOLENTLY STARBURSTING CORE AT z = 2.506.

Author

Tao Wang, David Elbaz, Emanuele Daddi, Alexis Finoguenov, Daizhong Liu, Corentin Schreiber, Sergio Martín, Veronica Strazzullo, Francesco Valentino, Remco van der Burg, Anita Zanella, Laure Ciesla, Raphael Gobat, Amandine Le Brun, Maurilio Pannella, Mark Sargent, Xinwen Shu, Qinghua Tan, Nico Cappelluti, and Yanxia Li

Subjects

GALAXY clusters, X-ray emission spectroscopy, GALAXY formation, GALACTIC evolution, STELLAR mass

Abstract

We report the discovery of a remarkable concentration of massive galaxies with extended X-ray emission at zspec = 2.506, which contains 11 massive (M* ≳ 1011M⊙) galaxies in the central 80 kpc region (11.6σ overdensity). We have spectroscopically confirmed 17 member galaxies with 11 from CO and the remaining ones from Hα. The X-ray luminosity, stellar mass content, and velocity dispersion all point to a collapsed, cluster-sized dark matter halo with mass M200c = 1013.9±0.2M⊙, making it the most distant X-ray-detected cluster known to date. Unlike other clusters discovered so far, this structure is dominated by star-forming galaxies (SFGs) in the core with only 2 out of the 11 massive galaxies classified as quiescent. The star formation rate (SFR) in the 80 kpc core reaches ∼3400 M⊙ yr−1 with a gas depletion time of ∼200 Myr, suggesting that we caught this cluster in rapid build-up of a dense core. The high SFR is driven by both a high abundance of SFGs and a higher starburst fraction (∼25%, compared to 3%–5% in the field). The presence of both a collapsed, cluster-sized halo and a predominant population of massive SFGs suggests that this structure could represent an important transition phase between protoclusters and mature clusters. It provides evidence that the main phase of massive galaxy passivization will take place after galaxies accrete onto the cluster, providing new insights into massive cluster formation at early epochs. The large integrated stellar mass at such high redshift challenges our understanding of massive cluster formation. [ABSTRACT FROM AUTHOR]

Published

2016