Your search keyword '"Tacconi, LJ"' showing total 4 results

1. Combined CO and dust scaling relations of depletion time and molecular gas fractions with cosmic time, specific star-formation rate, and stellar mass

Author

Genzel, R, Tacconi, LJ, Lutz, D, Saintonge, A, Berta, S, Magnelli, B, Combes, F, García-Burillo, S, Neri, R, Bolatto, A, Contini, T, Lilly, S, Boissier, J, Boone, F, Bouché, N, Bournaud, F, Burkert, A, Carollo, M, Colina, L, Cooper, MC, Cox, P, Feruglio, C, Förster Schreiber, NM, Freundlich, J, Gracia-Carpio, J, Juneau, S, Kovac, K, Lippa, M, Naab, T, Salome, P, Renzini, A, Sternberg, A, Walter, F, Weiner, B, Weiss, A, and Wuyts, S

Subjects

galaxies: evolution, galaxies: high-redshift, galaxies: kinematics and dynamics, infrared: galaxies, astro-ph.GA, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

We combine molecular gas masses inferred from CO emission in 500 star-forming galaxies (SFGs) between z = 0 and 3, from the IRAM-COLDGASS, PHIBSS1/2, and other surveys, with gas masses derived from Herschel far-IR dust measurements in 512 galaxy stacks over the same stellar mass/redshift range. We constrain the scaling relations of molecular gas depletion timescale (tdepl) and gas to stellar mass ratio (Mmol gas/M∗) of SFGs near the star formation "main-sequence" with redshift, specific star-formation rate (sSFR), and stellar mass (M∗). The CO- and dust-based scaling relations agree remarkably well. This suggests that the CO → H2 mass conversion factor varies little within ±0.6 dex of the main sequence (sSFR(ms, z, M∗)), and less than 0.3 dex throughout this redshift range. This study builds on and strengthens the results of earlier work. We find that tdepl scales as (1 + z)-0.3 × (sSFR/sSFR(ms, z, M∗))-0.5, with little dependence on M∗. The resulting steep redshift dependence of Mmol gas/M∗≈ (1 + z)3 mirrors that of the sSFR and probably reflects the gas supply rate. The decreasing gas fractions at high M∗are driven by the flattening of the SFR-M∗relation. Throughout the probed redshift range a combination of an increasing gas fraction and a decreasing depletion timescale causes a larger sSFR at constant M∗. As a result, galaxy integrated samples of the Mmol gas-SFR rate relation exhibit a super-linear slope, which increases with the range of sSFR. With these new relations it is now possible to determine Mmol gas with an accuracy of ±0.1 dex in relative terms, and ±0.2 dex including systematic uncertainties.

Published

2015

2. PHIBSS: Molecular gas, extinction, star formation, and kinematics in the z = 1.5 star-forming galaxy EGS13011166

Author

Genzel, R, Tacconi, LJ, Kurk, J, Wuyts, S, Combes, F, Freundlich, J, Bolatto, A, Cooper, MC, Neri, R, Nordon, R, Bournaud, F, Burkert, A, Comerford, J, Cox, P, Davis, M, Förster Schreiber, NM, García-Burillo, S, Gracia-Carpio, J, Lutz, D, Naab, T, Newman, S, Saintonge, A, Shapiro Griffin, K, Shapley, A, Sternberg, A, and Weiner, B

Subjects

galaxies: evolution, galaxies: high-redshift, galaxies: ISM, ISM: molecules, stars: formation, astro-ph.CO, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

We report matched resolution imaging spectroscopy of the CO 3-2 e (with the IRAM Plateau de Bure millimeter interferometer) and of the Hα e (with LUCI at the Large Binocular Telescope) in the massive z = 1.53 main-sequence galaxy EGS 13011166, as part of the "Plateau de Bure high-z, blue-sequence survey" (PHIBSS: Tacconi et al.). We combine these data with Hubble Space Telescope V-I-J-H-band maps to derive spatially resolved distributions of stellar surface density, star formation rate, molecular gas surface density, optical extinction, and gas kinematics. The spatial distribution and kinematics of the ionized and molecular gas are remarkably similar and are well modeled by a turbulent, globally Toomre unstable, rotating disk. The stellar surface density distribution is smoother than the clumpy rest-frame UV/optical light distribution and peaks in an obscured, star-forming massive bulge near the dynamical center. The molecular gas surface density and the effective optical screen extinction track each other and are well modeled by a "mixed" extinction model. The inferred slope of the spatially resolved molecular gas to star formation rate relation, N = dlogΣstar form/dlogΣmol gas, depends strongly on the adopted extinction model, and can vary from 0.8 to 1.7. For the preferred mixed dust-gas model, we find N = 1.14 ± 0.1. © 2013. The American Astronomical Society. All rights reserved.

Published

2013

3. The role of molecular gas in obscuring Seyfert active galactic nuclei

Author

Hicks, EKS, Davies, RI, Malkan, MA, Genzel, R, Tacconi, LJ, Müller Sánchez, F, and Sternberg, A

Subjects

galaxies: active, galaxies: kinematics and dynamics, galaxies: nuclei, galaxies: Seyfert, infrared: galaxies, astro-ph.GA, astro-ph.CO, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

In a sample of local active galactic nuclei (AGNs) studied at a spatial resolution on the order of 10 pc, we show that the interstellar medium traced by the molecular hydrogen ν = 1-0 S(1) line at 2.1 μm forms a geometrically thick, clumpy disk. The kinematics of the molecular gas reveals general rotation, although an additional significant component of random bulk motion is required by the high local velocity dispersion. The size scale of the typical gas disk is found to have a radius of ∼30 pc with a comparable vertical height. Within this radius, the average gas mass is estimated to be ∼10 7 M⊙ based on a typical gas mass fraction of 10%, which suggests column densities of NH ∼ 5 × 1023 cm-2. Extinction of the stellar continuum within this same region suggests lower column densities of NH ∼ 2 × 1022 cm-2, indicating that the gas distribution on these scales is dominated by dense clumps. In half of the observed Seyfert galaxies, this lower column density is still great enough to obscure the AGN at optical/infrared wavelengths. We conclude, based on the spatial distribution, kinematics, and column densities that the molecular gas observed is spatially mixed with the nuclear stellar population and is likely to be associated with the outer extent of any smaller scale nuclear obscuring structure. Furthermore, we find that the velocity dispersion of the molecular gas is correlated with the star formation rate per unit area, suggesting a link between the two phenomena, and that the gas surface density follows known "Schmidt-Kennicutt" relations. The molecular/dusty structure on these scales may be dynamic since it is possible that the velocity dispersion of the gas, and hence the vertical disk height, is maintained by a short, massive inflow of material into the nuclear region and/or by intense, short-lived nuclear star formation. © 2009. The American Astronomical Society.

Published

2009

4. THE SINS SURVEY: SINFONI INTEGRAL FIELD SPECTROSCOPY OF z similar to 2 STAR-FORMING GALAXIES

Author

Schreiber, NMF, Genzel, R, Bouche, N, Cresci, G, Davies, R, Buschkamp, P, Shapiro, K, Tacconi, LJ, Hicks, EKS, Genel, S, Shapley, AE, Erb, DK, Steidel, CC, Lutz, D, Eisenhauer, F, Gillessen, S, Sternberg, A, Renzini, A, Cimatti, A, Daddi, E, Kurk, J, Lilly, S, Kong, X, Lehnert, MD, Nesvadba, N, Verma, A, McCracken, H, Arimoto, N, Mignoli, M, and Onodera, M

Subjects

Astrophysics::Earth and Planetary Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics::Galaxy Astrophysics

Abstract

We present the Spectroscopic Imaging survey in the near-infrared (near-IR) with SINFONI (SINS) of high-redshift galaxies. With 80 objects observed and 63 detected in at least one rest-frame optical nebular emission line, mainly Hα, SINS represents the largest survey of spatially resolved gas kinematics, morphologies, and physical properties of star-forming galaxies at z 1-3. We describe the selection of the targets, the observations, and the data reduction. We then focus on the "SINS Hα sample," consisting of 62 rest-UV/optically selected sources at 1.3 < z < 2.6 for which we targeted primarily the Hα and [N II] emission lines. Only ≈ 30% of this sample had previous near-IR spectroscopic observations. The galaxies were drawn from various imaging surveys with different photometric criteria; as a whole, the SINS Hα sample covers a reasonable representation of massive M* ≳ 1010 M ·star-forming galaxies at z 1.5-2.5, with some bias toward bluer systems compared to pure K-selected samples due to the requirement of secure optical redshift. The sample spans 2 orders of magnitude in stellar mass and in absolute and specific star formation rates, with median values ≈ 3 × 1010 M ·, ≈ 70 M· yr-1, and 3 Gyr-1. The ionized gas distribution and kinematics are spatially resolved on scales ranging from 1.5 kpc for adaptive optics assisted observations to typically 4-5 kpc for seeing-limited data. The Hα morphologies tend to be irregular and/or clumpy. About one-third of the SINS Hα sample galaxies are rotation-dominated yet turbulent disks, another one-third comprises compact and velocity dispersion-dominated objects, and the remaining galaxies are clear interacting/merging systems; the fraction of rotation-dominated systems increases among the more massive part of the sample. The Hα luminosities and equivalent widths suggest on average roughly twice higher dust attenuation toward the H II regions relative to the bulk of the stars, and comparable current and past-averaged star formation rates. © 2009. The American Astronomical Society.

Published

2009