Your search keyword '"Griffin, Kristen Shapiro"' showing total 4 results

1. NEBULAR EXCITATION IN z ∼ 2 STAR-FORMING GALAXIES FROM THE SINS AND LUCI SURVEYS: THE INFLUENCE OF SHOCKS AND ACTIVE GALACTIC NUCLEIBased on observations at the Very Large Telescope (VLT) of the European Southern Observatory (ESO), Paranal, Chile (ESO program IDs 073.B-9018, 076.A-0527, 079.A-0341, 080.A-0330, 080.A-0339, 080.A-0635, 083.A-0781,084.A-0853, 087.A-0081, 091.A.-0126) and at the Large Binocular Telescope (LBT) on Mt. Graham in Arizona.

Author

Newman, Sarah F., Buschkamp, Peter, Genzel, Reinhard, Schreiber, Natascha M. Förster, Kurk, Jaron, Sternberg, Amiel, Gnat, Orly, Rosario, David, Mancini, Chiara, Lilly, Simon J., Renzini, Alvio, Burkert, Andreas, Carollo, C. Marcella, Cresci, Giovanni, Davies, Ric, Eisenhauer, Frank, Genel, Shy, Griffin, Kristen Shapiro, Hicks, Erin K. S., and Lutz, Dieter

Subjects

GALAXY formation, ACTIVE galactic nuclei, PHOTOIONIZATION, GALACTIC redshift, REDSHIFT

Abstract

Based on high-resolution, spatially resolved data of 10 z ∼ 2 star-forming galaxies from the SINS/zC-SINF survey and LUCI data for 12 additional galaxies, we probe the excitation properties of high-z galaxies and the impact of active galactic nuclei (AGNs), shocks, and photoionization. We explore how these spatially resolved line ratios can inform our interpretation of integrated emission line ratios obtained at high redshift. Many of our galaxies fall in the “composite” region of the z ∼ 0 [N II]/Hα versus [O III]/Hβ diagnostic (BPT) diagram, between star-forming galaxies and those with AGNs. Based on our resolved measurements, we find that some of these galaxies likely host an AGN, while others appear to be affected by the presence of shocks possibly caused by an outflow or from an enhanced ionization parameter as compared with H II regions in normal, local star-forming galaxies. We find that the Mass-Excitation (MEx) diagnostic, which separates purely star-forming and AGN hosting local galaxies in the [O III]/Hβ versus stellar mass plane, does not properly separate z ∼ 2 galaxies classified according to the BPT diagram. However, if we shift the galaxies based on the offset between the local and z ∼ 2 mass-metallicity relation (i.e., to the mass they would have at z ∼ 0 with the same metallicity), we find better agreement between the MEx and BPT diagnostics. Finally, we find that metallicity calibrations based on [N II]/Hα are more biased by shocks and AGNs at high-z than the [O III]/Hβ/[N II]/Hα calibration. [ABSTRACT FROM AUTHOR]

Published

2014

2. NGC 1266 AS A LOCAL CANDIDATE FOR RAPID CESSATION OF STAR FORMATION.

Author

Alatalo, Katherine, Nyland, Kristina, Graves, Genevieve, Deustua, Susana, Griffin, Kristen Shapiro, Duc, Pierre-Alain, Cappellari, Michele, McDermid, Richard M., Davis, Timothy A., Crocker, Alison F., Young, Lisa M., Chang, Philip, Scott, Nicholas, Cales, Sabrina L., Bayet, Estelle, Blitz, Leo, Bois, Maxime, Bournaud, Frédéric, Bureau, Martin, and Davies, Roger L.

Subjects

STAR formation, INTEGRAL field spectroscopy, OPTICAL telescopes, ASTRONOMICAL observations, ACTIVE galactic nuclei, ACTIVE galaxies

Abstract

We present new Spectrographic Areal Unit for Research on Optical Nebulae (SAURON) integral-field spectroscopy and Swift Ultraviolet Optical Telescope (UVOT) observations of molecular outflow host galaxy NGC 1266 that indicate NGC 1266 has experienced a rapid cessation of star formation. Both the SAURON maps of stellar population age and the Swift UVOT observations demonstrate the presence of young (<1 Gyr) stellar populations within the central 1 kpc, while existing Combined Array for Research in Millimeter-Wave Astronomy CO(1-0) maps indicate that the sites of current star formation are constrained to only the inner few hundred parsecs of the galaxy. The optical spectrum of NGC 1266 from Moustakas & Kennicutt reveal a characteristic poststarburst (K+A) stellar population, and Davis et al. confirm that ionized gas emission in the system originate from a shock. Galaxies with K+A spectra and shock-like ionized gas line ratios may comprise an important, overlooked segment of the poststarburst population, containing exactly those objects in which the active galactic nucleus (AGN) is actively expelling the star-forming material. While AGN activity is not the likely driver of the poststarburst event that occurred 500 Myr ago, the faint spiral structure seen in the Hubble Space Telescope Wide-field Camera 3 Y-, J- and H-band imaging seems to point to the possibility of gravitational torques being the culprit. If the molecular gas were driven into the center at the same time as the larger scale galaxy disk underwent quenching, the AGN might be able to sustain the presence of molecular gas for ≳ 1 Gyr by cyclically injecting turbulent energy into the dense molecular gas via a radio jet, inhibiting star formation. [ABSTRACT FROM AUTHOR]

Published

2014

3. THE SINS/zC-SINF SURVEY OF z ~ 2 GALAXY KINEMATICS: THE NATURE OF DISPERSION-DOMINATED GALAXIES.

Author

NEWMAN, SARAH F., GENZEL, REINHARD, SCHREIBER, NATASCHA M. FÖRSTER, GRIFFIN, KRISTEN SHAPIRO, MANCINI, CHIARA, LILLY, SIMON J., RENZINI, ALVIO, BOUCHÉ, NICOLAS, BURKERT, ANDREAS, BUSCHKAMP, PETER, CAROLLO, C. MARCELLA, CRESCI, GIOVANNI, DAVIES, RIC, EISENHAUER, FRANK, GENEL, SHY, HICKS, ERIN K. S., KURK, JARON, LUTZ, DIETER, NAAB, THORSTEN, and PENG, YINGJIE

Subjects

KINEMATICS, OPTICS, INFRARED astronomy, VELOCITY, MILKY Way

Abstract

We analyze the spectra, spatial distributions, and kinematics of Hα, [NII], and [S II] emission in a sample of 38, z ~ 2.2 UV/optically selected star-forming galaxies (SFGs) from the SINS and zC-SINF surveys, 34 of which were observed in the adaptive optics mode of SINFONI and 30 of those contain data presented for the first time here. This is supplemented by kinematic data from 43 z ~ 1-2.5 galaxies from the literature. None of these 81 galaxies is an obvious major merger. We find that the kinematic classification of high-z SFGs as "dispersion dominated" or rotation dominated" correlates most strongly with their intrinsic sizes. Smaller galaxies are more likely "dispersion-dominated" for two main reasons: (1) the rotation velocity scales linearly with galaxy size but intrinsic velocity dispersion does not depend on size or may even increase in smaller galaxies, and as such, their ratio is systematically lower for smaller galaxies, and (2) beam smearing strongly decreases large-scale velocity gradients and increases observed dispersion much more for galaxies with sizes at or below the resolution. Dispersion-dominated SFGs may thus have intrinsic properties similar to "rotation-dominated" SFGs, but are primarily more compact, lower mass, less metal enriched, and may have higher gas fractions, plausibly because they represent an earlier evolutionary state. [ABSTRACT FROM AUTHOR]

Published

2013

4. THE SINS/zC-SINF SURVEY of z ∼ 2 GALAXY KINEMATICS: OUTFLOW PROPERTIES.

Author

Newman, Sarah F., Genzel, Reinhard, Förster-Schreiber, Natascha M., Griffin, Kristen Shapiro, Mancini, Chiara, Lilly, Simon J., Renzini, Alvio, Bouché, Nicolas, Burkert, Andreas, Buschkamp, Peter, Carollo, C. Marcella, Cresci, Giovanni, Davies, Ric, Eisenhauer, Frank, Genel, Shy, Hicks, Erin K. S., Kurk, Jaron, Lutz, Dieter, Naab, Thorsten, and Peng, Yingjie

Subjects

STAR formation, GALAXIES, INFRARED astronomy, INFRARED radiation, STELLAR evolution

Abstract

Using SINFONI Hα, [N II], and [S II] AO data of 27 z ∼ 2 star-forming galaxies (SFGs) from the SINS and zC-SINF surveys, we explore the dependence of outflow strength (via the broad flux fraction) on various galaxy parameters. For galaxies that have evidence for strong outflows, we find that the broad emission is spatially extended to at least the half-light radius (∼a few kpc). Decomposition of the [S II] doublet into broad and narrow components suggests that this outflowing gas probably has a density of ∼10-100 cm–3, less than that of the star-forming gas (600 cm–3). There is a strong correlation of the Hα broad flux fraction with the star formation surface density of the galaxy, with an apparent threshold for strong outflows occurring at 1 M☼ yr–1 kpc–2. Above this threshold, we find that SFGs with log m* > 10 have similar or perhaps greater wind mass-loading factors (η = /SFR) and faster outflow velocities than lower mass SFGs, suggesting that the majority of outflowing gas at z ∼ 2 may derive from high-mass SFGs. The mass-loading factor is also correlated with the star formation rate (SFR), galaxy size, and inclination, such that smaller, more star-forming, and face-on galaxies launch more powerful outflows. We propose that the observed threshold for strong outflows and the observed mass loading of these winds can be explained by a simple model wherein break-out of winds is governed by pressure balance in the disk. [ABSTRACT FROM AUTHOR]

Published

2012