Your search keyword '"Hwihyun Kim"' showing total 15 results

1. H2, CO, and Dust Absorption through Cold Molecular Clouds.

Author

John H. Lacy, Christopher Sneden, Hwihyun Kim, and Daniel T. Jaffe

Subjects

*INFRARED absorption, *INTERSTELLAR hydrogen, *COSMIC dust, *CARBON monoxide, *MOLECULAR clouds, *TAURUS (Astrology), *COSMIC abundances

Abstract

The abundance of H2 in molecular clouds, relative to the commonly used tracer CO, has only been measured toward a few embedded stars, which may be surrounded by atypical gas. We present observations of near-infrared absorption by H2, CO, and dust toward stars behind molecular clouds, providing a representative sample of these molecules in cold molecular gas, primarily in the Taurus Molecular Cloud. We find ≈ 1.0 × 1021 cm−2, ≈ 1.5 × 1017 cm−2 (1.8 × 1017 including solid CO), and ≈ 6000. The measured ratio is consistent with that toward embedded stars in various molecular clouds, but both are less than that derived from millimeter-wave observations of CO and star counts. The difference apparently results from the higher directly measured ratio. [ABSTRACT FROM AUTHOR]

Published

2017

2. Hierarchical star formation across the ring galaxy NGC 6503.

Author

Gouliermis, Dimitrios A., Thilker, David, Elmegreen, Bruce G., Elmegreen, Debra M., Calzetti, Daniela, Lee, Janice C., Adamo, Angela, Aloisi, Alessandra, Cignoni, Michele, Cook, David O., Dale, Daniel A., Gallagher III, John S., Grasha, Kathryn, Grebel, Eva K., Davó, Artemio Herrero, Hunter, Deidre A., Johnson, Kelsey E., Hwihyun Kim, Nair, Preethi, and Nota, Antonella

Subjects

*STAR formation, *STELLAR structure, *STELLAR populations, *STELLAR mass, *ASTRONOMICAL photometry

Abstract

We present a detailed clustering analysis of the young stellar population across the star-forming ring galaxy NGC 6503, based on the deep Hubble Space Telescope photometry obtained with the Legacy ExtraGalactic UV Survey. We apply a contour-based map analysis technique and identify in the stellar surface density map 244 distinct star-forming structures at various levels of significance. These stellar complexes are found to be organized in a hierarchical fashion with 95 percent being members of three dominant super-structures located along the star-forming ring. The size distribution of the identified structures and the correlation between their radii and numbers of stellar members show power-law behaviours, as expected from scale-free processes. The self-similar distribution of young stars is further quantified from their autocorrelation function, with a fractal dimension of ~1.7 for length-scales between ~20 pc and 2.5 kpc. The young stellar radial distribution sets the extent of the star-forming ring at radial distances between 1 and 2.5 kpc. About 60 percent of the young stars belong to the detected stellar structures, while the remaining stars are distributed among the complexes, still inside the ring of the galaxy. The analysis of the time-dependent clustering of young populations shows a significant change from a more clustered to a more distributed behaviour in a time-scale of ~60 Myr. The observed hierarchy in stellar clustering is consistent with star formation being regulated by turbulence across the ring. The rotational velocity difference between the edges of the ring suggests shear as the driving mechanism for this process. Our findings reveal the interesting case of an inner ring forming stars in a hierarchical fashion. [ABSTRACT FROM AUTHOR]

Published

2015

3. LEGUS and H α -LEGUS Observations of Star Clusters in NGC 4449: Improved Ages and the Fraction of Light in Clusters as a Function of Age.

Author

Bradley C. Whitmore, Rupali Chandar, Janice Lee, Leonardo Ubeda, Angela Adamo, Alessandra Aloisi, Daniela Calzetti, Michele Cignoni, David Cook, Daniel Dale, B. G. Elmegreen, Dimitrios Gouliermis, Eva K. Grebel, Kathryn Grasha, Kelsey E. Johnson, Hwihyun Kim, Elena Sacchi, Linda J. Smith, Monica Tosi, and Aida Wofford

Subjects

*STAR observations, *AGE distribution, *STARBURSTS, *AGE of stars, *STAR formation, *STELLAR populations, *STAR clusters

Abstract

We present a new catalog and results for the cluster system of the starburst galaxy NGC 4449, based on multiband imaging observations taken as part of the LEGUS and Hα-LEGUS surveys. We improve the spectral energy fitting method used to estimate cluster ages, and find that the results, particularly for older clusters, are in better agreement with those from spectroscopy. The inclusion of Hα measurements, the role of stochasticity for low-mass clusters, the assumptions about reddening, and the choices of SSP model and metallicity all have important impacts on the age dating of clusters. A comparison with ages derived from stellar color–magnitude diagrams for partially resolved clusters shows reasonable agreement, but large scatter in some cases. The fraction of light found in clusters relative to the total light (i.e., TL) in the U, B, and V filters in 25 different ≈ kiloparsec-size regions throughout NGC 4449 correlates with both the specific region luminosity, RL, and the dominant age of the underlying stellar population in each region. The observed cluster age distribution is found to decline over time as dN/dτ ∝ τγ, with γ = −0.85 ± 0.15, independent of cluster mass, and is consistent with strong, early cluster disruption. The mass functions of the clusters can be described by a power law with dN/dM ∝ Mβ and β = −1.86 ± 0.2, independent of cluster age. The mass and age distributions are quite resilient to differences in age-dating methods. There is tentative evidence for a factor of 2–3 enhancement in both the star and cluster formation rate ≈100–300 Myr ago, indicating that cluster formation tracks star formation generally. The enhancement is probably associated with an earlier interaction event. [ABSTRACT FROM AUTHOR]

Published

2020

4. Chemical Compositions of Evolved Stars from Near-infrared IGRINS High-resolution Spectra. I. Abundances in Three Red Horizontal Branch Stars.

Author

Melike Afşar, Christopher Sneden, Michael P. Wood, James E. Lawler, Zeynep Bozkurt, Gamze Böcek Topcu, Gregory N. Mace, Hwihyun Kim, and Daniel T. Jaffe

Subjects

*COSMIC abundances, *STELLAR evolution, *STELLAR atmospheres, *HORIZONTAL branch stars, *GLOBULAR clusters

Abstract

We have derived elemental abundances of three field red horizontal branch stars using high-resolution (R ≃ 45,000), high signal-to-noise ratio (S/N ≳ 200) H- and K-band spectra obtained with the Immersion Grating Infrared Spectrograph (IGRINS). We have determined the abundances of 21 elements, including α (Mg, Si, Ca, S), odd-Z (Na, Al, P, K), Fe-group (Sc, Ti, Cr, Co, Ni), neutron-capture (Ce, Nd, Yb), CNO-group elements. S, P, and K are determined for the first time in these stars. H- and K-band spectra provide a substantial number of S i lines, which potentially can lead to a more robust exploration of the role of sulfur in the cosmochemical evolution of the Galaxy. We have also derived 12C/13C ratios from synthetic spectra of the first-overtone 12CO (2–0) and (3–1) and 13CO (2–0) lines near 23440 Å and 13CO (3–1) lines at about 23730 Å. Comparison of our results with the ones obtained from the optical region suggests that the IGRINS high-resolution H- and K-band spectra offer more internally self-consistent line abundances of the same species for several elements, especially the α-elements. This in turn provides more reliable abundances for the elements with analytical difficulties in the optical spectral range. [ABSTRACT FROM AUTHOR]

Published

2018

5. High-resolution Near-IR Spectral Mapping with H2 and [Fe ii] Lines of Multiple Outflows around LkHα 234.

Author

Heeyoung Oh, Tae-Soo Pyo, Bon-Chul Koo, In-Soo Yuk, Kyle F. Kaplan, Yong-Hyun Lee, Kimberly R. Sokal, Gregory N. Mace, Chan Park, Jae-Joon Lee, Byeong-Gon Park, Narae Hwang, Hwihyun Kim, and Daniel T. Jaffe

Subjects

*STAR formation, *COMPLEX multiplication, *VERY large array telescopes, *JETS (Nuclear physics), *PHOTODISSOCIATION

Abstract

We present a high-resolution, near-IR spectroscopic study of multiple outflows in the LkHα 234 star formation region using the Immersion GRating INfrared Spectrometer (IGRINS). Spectral mapping over the blueshifted emission of HH 167 allowed us to distinguish at least three separate, spatially overlapped outflows in H2 and [Fe ii] emission. We show that the H2 emission represents not a single jet but rather complex multiple outflows driven by three known embedded sources: MM1, VLA 2, and VLA 3. There is a redshifted H2 outflow at a low velocity, VLSR <+50 km s−1, with respect to the systemic velocity of VLSR = −11.5 km s−1, that coincides with the H2O masers seen in earlier radio observations 2″ southwest of VLA 2. We found that the previously detected [Fe ii] jet with 100 km s−1 driven by VLA 3B is also detected in H2 emission and confirm that this jet has a position angle of about 240°. Spectra of the redshifted knots at 14″–65″ northeast of LkHα 234 are presented for the first time. These spectra also provide clues to the existence of multiple outflows. We detected high-velocity (50–120 km s−1) H2 gas in the multiple outflows around LkHα 234. Since these gases move at speeds well over the dissociation velocity (>40 km s−1), the emission must originate from the jet itself rather than H2 gas in the ambient medium. Also, position–velocity and excitation diagrams indicate that emission from knot C in HH 167 comes from two different phenomena, shocks and photodissociation. [ABSTRACT FROM AUTHOR]

Published

2018

6. A Study of Two Dwarf Irregular Galaxies with Asymmetrical Star Formation Distributions.

Author

Deidre A. Hunter, Samavarti Gallardo, Hong-Xin Zhang, Angela Adamo, David O. Cook, Se-Heon Oh, Bruce G. Elmegreen, Hwihyun Kim, Lauren Kahre, Leonardo Ubeda, Stacey N. Bright, Jenna E. Ryon, Michele Fumagalli, Elena Sacchi, R. C. Kennicutt, Monica Tosi, Daniel A. Dale, Michele Cignoni, Matteo Messa, and Eva K. Grebel

Subjects

*DWARF irregular galaxies, *STAR formation, *STAR colors, *MOLECULAR clouds, *PRESSURE, *INTERSTELLAR molecules

Abstract

Two dwarf irregular galaxies, DDO 187 and NGC 3738, exhibit a striking pattern of star formation: intense star formation is taking place in a large region occupying roughly half of the inner part of the optical galaxy. We use data on the H i distribution and kinematics and stellar images and colors to examine the properties of the environment in the high star formation rate (HSF) halves of the galaxies in comparison with the low star formation rate halves. We find that the pressure and gas density are higher on the HSF sides by 30%–70%. In addition we find in both galaxies that the H i velocity fields exhibit significant deviations from ordered rotation and there are large regions of high-velocity dispersion and multiple velocity components in the gas beyond the inner regions of the galaxies. The conditions in the HSF regions are likely the result of large-scale external processes affecting the internal environment of the galaxies and enabling the current star formation there. [ABSTRACT FROM AUTHOR]

Published

2018

7. Wolf 1130: A Nearby Triple System Containing a Cool, Ultramassive White Dwarf.

Author

Gregory N. Mace, Andrew W. Mann, Brian A. Skiff, Christopher Sneden, J. Davy Kirkpatrick, Adam C. Schneider, Benjamin Kidder, Natalie M. Gosnell, Hwihyun Kim, Brian W. Mulligan, L. Prato, and Daniel Jaffe

Subjects

*WHITE dwarf stars, *BINARY systems (Astronomy), *ASTRONOMICAL photometry, *ATOMIC mass, *STAR observations

Abstract

Following the discovery of the T8 subdwarf WISE J200520.38+542433.9 (Wolf 1130C), which has a proper motion in common with a binary (Wolf 1130AB) consisting of an M subdwarf and a white dwarf, we set out to learn more about the old binary in the system. We find that the A and B components of Wolf 1130 are tidally locked, which is revealed by the coherence of more than a year of V-band photometry phase-folded to the derived orbital period of 0.4967 days. Forty new high-resolution, near-infrared spectra obtained with the Immersion Grating Infrared Spectrometer provide radial velocities and a projected rotational velocity (v sin i) of 14.7 ± 0.7 for the M subdwarf. In tandem with a Gaia parallax-derived radius and verified tidal locking, we calculate an inclination of i = 29° ± 2°. From the single-lined orbital solution and the inclination we derive an absolute mass for the unseen primary ( M⊙). Its non-detection between 0.2 and 2.5 μm implies that it is an old (>3.7 Gyr) and cool (Teff < 7000 K) ONe white dwarf. This is the first ultramassive white dwarf within 25 pc. The evolution of Wolf 1130AB into a cataclysmic variable is inevitable, making it a potential SN Ia progenitor. The formation of a triple system with a primary mass >100 times the tertiary mass and the survival of the system through the common-envelope phase, where ∼80% of the system mass was lost, is remarkable. Our analysis of Wolf 1130 allows us to infer its formation and evolutionary history, which has unique implications for understanding low-mass star and brown dwarf formation around intermediate-mass stars. [ABSTRACT FROM AUTHOR]

Published

2018

8. Characterizing TW Hydra.

Author

Kimberly R. Sokal, Casey P. Deen, Gregory N. Mace, Jae-Joon Lee, Heeyoung Oh, Hwihyun Kim, Benjamin T. Kidder, and Daniel T. Jaffe

Subjects

*PROTOPLANETARY disks, *NEAR infrared radiation, *DISKS (Astrophysics), *STAR formation, *TEMPERATURE effect

Abstract

At 60 pc, TW Hydra (TW Hya) is the closest example of a star with a gas-rich protoplanetary disk, though TW Hya may be relatively old (3–15 Myr). As such, TW Hya is especially appealing for testing our understanding of the interplay between stellar and disk evolution. We present a high-resolution near-infrared spectrum of TW Hya obtained with the Immersion GRating INfrared Spectrometer (IGRINS) to re-evaluate the stellar parameters of TW Hya. We compare these data to synthetic spectra of magnetic stars produced by MoogStokes, and use sensitive spectral line profiles to probe the effective temperature, surface gravity, and magnetic field. A model with K, , and kG best fits the near-infrared spectrum of TW Hya. These results correspond to a spectral type of M0.5 and an age of 8 Myr, which is well past the median life of gaseous disks. [ABSTRACT FROM AUTHOR]

Published

2018

9. Inner Warm Disk of ESO Hα 279a Revealed by NA i and CO Overtone Emission Lines.

Author

A-Ran Lyo, Jongsoo Kim, Jae-Joon Lee, Kyoung-Hee Kim, Jihyun Kang, Do-Young Byun, Gregory Mace, Kimberly R. Sokal, Chan Park, Moo-Young Chun, Heeyoung Oh, Young Sam Yu, Jae Sok Oh, Ueejeong Jeong, Hwihyun Kim, Soojong Pak, Narae Hwang, Byeong-Gon Park, Sungho Lee, and Kyle Kaplan

Subjects

*HIGH resolution spectroscopy, *ASTRONOMICAL spectroscopy, *STAR formation, *PROTOPLANETARY disks, *IR spectrometers, *PROTOSTARS

Abstract

We present an analysis of near-infrared, high-resolution spectroscopy toward the flat-spectrum young stellar object (YSO) ESO Hα 279a (∼1.5M⊙) in the Serpens star-forming region at a distance of 429 pc. Using the Immersion GRating INfrared Spectrometer (IGRINS; R ≈ 45,000), we detect emission lines originating from the accretion channel flow, jet, and inner disk. Specifically, we identify hydrogen Brackett series recombination, [Fe ii], [Fe iii], [Fe iv], Ca i, Na i, H2, H2O, and CO overtone emission lines. By modeling five bands of CO overtone emission lines and the symmetric double-peaked line profile for Na i emission lines, we find that ESO Hα 279a has an actively accreting Keplerian disk. From our Keplerian disk model, we find that Na i emission lines originate between 0.04 and 1.00 au, while the CO overtone emission lines are from the outer part of the disk, in the range between 0.22 and 3.00 au. The model reveals that the neutral atomic Na gas is a good tracer of the innermost region of the actively accreting disk. We derive a mass accretion rate of M⊙ yr−1 from the measured Brγ emission luminosity of 1.78(±0.31) × 1031 erg s−1. [ABSTRACT FROM AUTHOR]

Published

2017

10. The Spectrum of SS 433 in the H and K Bands.

Author

Edward L. Robinson, Cynthia S. Froning, Daniel T. Jaffe, Kyle F. Kaplan, Hwihyun Kim, Gregory N. Mace, Kimberly R. Sokal, and Jae-Joon Lee

Subjects

*X-ray binaries, *X-ray spectra, *STELLAR spectra, *SPECTROGRAMS, *RADIO jets (Astrophysics)

Abstract

SS 433 is an X-ray binary and the source of sub-relativistic, precessing, baryonic jets. We present high-resolution spectrograms of SS 433 in the infrared H and K bands. The spectrum is dominated by hydrogen and helium emission lines. The precession phase of the emission lines from the jet continues to be described by a constant period, . The limit on any secularly changing period is . The He i line has complex and variable P-Cygni absorption features produced by an inhomogeneous wind with a maximum outflow velocity near 900 km s−1. The He ii emission lines in the spectrum also arise in this wind. The higher members of the hydrogen Brackett lines show a double-peaked profile with symmetric wings extending more than ±1500 km s−1 from the line center. The lines display radial velocity variations in phase with the radial velocity variation expected of the compact star, and they show a distortion during disk eclipse that we interpret as a rotational distortion. We fit the line profiles with a model in which the emission comes from the surface of a symmetric, Keplerian accretion disk around the compact object. The outer edge of the disk has velocities that vary from 110 to 190 km s−1. These comparatively low velocities place an important constraint on the mass of the compact star: its mass must be less than and is probably less than . [ABSTRACT FROM AUTHOR]

Published

2017

11. Excitation of Molecular Hydrogen in the Orion Bar PhotodissociationRegion from a Deep Near-infrared IGRINS Spectrum.

Author

Kyle F. Kaplan, Harriet L. Dinerstein, Heeyoung Oh, Gregory N. Mace, Hwihyun Kim, Kimberly R. Sokal, Michael D. Pavel, Sungho Lee, Soojong Pak, Chan Park, Jae Sok Oh, and Daniel T. Jaffe

Subjects

*EXCITATION energy (In situ microanalysis), *WAVELENGTHS, *PHOTODISSOCIATION, *ASTROPHYSICS, *ASTRONOMICAL observatories

Abstract

We present a deep near-infrared spectrum of the Orion Bar Photodissociation Region (PDR) taken with the Immersion Grating INfrared Spectrometer (IGRINS) on the 2.7 m telescope at the McDonald Observatory. IGRINS has high spectral resolution () and instantaneous broad wavelength coverage (1.45–2.45 μm), enabling us to detect 87 emission lines from rovibrationally excited molecular hydrogen (H2) that arise from transitions out of 69 upper rovibration levels of the electronic ground state. These levels cover a large range of rotational and vibrational quantum numbers and excitation energies, making them excellent probes of the excitation mechanisms of H2 and physical conditions within the PDR. The Orion Bar PDR is thought to consist of cooler high density clumps or filaments ( K, cm−3) embedded in a warmer lower density medium ( K, cm−3). We fit a grid of constant temperature and density Cloudy models, which recreate the observed H2 level populations well, to constrain the temperature to a range of 600–650 K and the density to cm−3. The best-fit model gives T = 625 K and cm−3. This well-constrained warm temperature is consistent with kinetic temperatures found by other studies for the Orion Bar’s lower density medium. However, the range of densities well fit by the model grid is marginally lower than those reported by other studies. We could be observing lower density gas than the surrounding medium, or perhaps a density-sensitive parameter in our models is not properly estimated. [ABSTRACT FROM AUTHOR]

Published

2017

12. THREE-DIMENSIONAL SHOCK STRUCTURE OF THE ORION KL OUTFLOW WITH IGRINS.

Author

Heeyoung Oh, Tae-Soo Pyo, Kyle Kaplan, In-Soo Yuk, Byeong-Gon Park, Gregory Mace, Chan Park, Moo-Young Chun, Soojong Pak, Kang-Min Kim, Jae Sok Oh, Ueejeong Jeong, Young Sam Yu, Jae-Joon Lee, Hwihyun Kim, Narae Hwang, Hye-In Lee, Huynh Anh Nguyen Le, Sungho Lee, and Daniel T. Jaffe

Subjects

*SPECTROSCOPIC imaging, *RADIAL velocity of stars, *THREE-dimensional imaging, *EMISSION-line galaxies, *ORION Nebula

Abstract

We report a study of the three-dimensional (3D) outflow structure of a 15″ × 13″ area around the H2 peak 1 in Orion KL with slit-scan observations (13 slits) using the Immersion Grating Infrared Spectrograph. The datacubes have a high-velocity resolution (∼7.5 km s−1), provide high-contrast imaging within ultra-narrow bands, and enable the detection of the main stream of the previously reported H2 outflow fingers. We identified 31 distinct fingers in the H2 1−0 S(1) λ2.122 μm emission. The line profile at each finger shows multiple-velocity peaks with a strong low-velocity component around the systemic velocity at = +8 km s−1 and high-velocity emission ( = 45–135 km s−1), indicating a typical bow-shock. The observed radial velocity gradients of ∼4 km s−1 arcsec−1 agree well with the velocities inferred from large-scale proper motions, where the projected motion is proportional to the distance from a common origin. We construct a conceptual 3D map of the fingers with estimated inclination angles of 57°–74°. The extinction difference (ΔAv > 10 mag) between blueshifted and redshifted fingers indicates high internal extinction. The extinction, the overall angular spread, and the scale of the flow argue for an ambient medium with a very high density (105–106 cm−3), consistent with molecular line observations of the Orion Molecular Cloud core. The radial velocity gradients and the 3D distributions of the fingers together support the hypothesis of a simultaneous radial explosion of the Orion KL outflow. [ABSTRACT FROM AUTHOR]

Published

2016

13. THE CHEMICAL COMPOSITIONS OF VERY METAL-POOR STARS HD 122563 AND HD 140283: A VIEW FROM THE INFRARED.

Author

Melike Afşar, Christopher Sneden, Anna Frebel, Hwihyun Kim, Gregory N. Mace, Kyle F. Kaplan, Hye-In Lee, Heeyoung Oh, Jae Sok Oh, Soojong Pak, Chan Park, Michael D. Pavel, In-Soo Yuk, and Daniel T. Jaffe

Subjects

*METAL-poor stars, *COSMIC abundances, *INFRARED astronomy, *OPTICAL wavelength conversion, *MICROWAVE reflectometry

Abstract

From high resolution (R ≃ 45,000), high signal-to-noise ratio (S/N > 400) spectra gathered with the Immersion Grating Infrared Spectrograph (IGRINS) in the H and K photometric bands, we have derived elemental abundances of two bright, well-known metal-poor halo stars: the red giant HD 122563 and the subgiant HD 140283. Since these stars have metallicities approaching [Fe/H] = −3, their absorption features are generally very weak. Neutral-species lines of Mg, Si, S and Ca are detectable, as well as those of the light odd-Z elements Na and Al. The derived IR-based abundances agree with those obtained from optical-wavelength spectra. For Mg and Si the abundances from the infrared transitions are improvements to those derived from shorter wavelength data. Many useful OH and CO lines can be detected in the IGRINS HD 122563 spectrum, from which derived O and C abundances are consistent to those obtained from the traditional [O i] and CH features. IGRINS high resolutions H- and K-band spectroscopy offers promising ways to determine more reliable abundances for additional metal-poor stars whose optical features are either not detectable, or too weak, or are based on lines with analytical difficulties. [ABSTRACT FROM AUTHOR]

Published

2016

14. IGRINS NEAR-IR HIGH-RESOLUTION SPECTROSCOPY OF MULTIPLE JETS AROUND LkHα 234.

Author

Heeyoung Oh, Tae-Soo Pyo, In-Soo Yuk, Byeong-Gon Park, Chan Park, Moo-Young Chun, Soojong Pak, Kang-Min Kim, Jae Sok Oh, Ueejeong Jeong, Young Sam Yu, Jae-Joon Lee, Hwihyun Kim, Narae Hwang, Kyle Kaplan, Michael Pavel, Gregory Mace, Hye-In Lee, Huynh Anh Nguyen Le, and Sungho Lee

Subjects

*SPECTRUM analysis, *SPECTROGRAPHS, *STELLAR evolution, *STARS, *BIPOLAR outflows (Astrophysics)

Abstract

We present the results of high-resolution near-IR spectroscopy toward the multiple outflows around the Herbig Be star LkHα 234 using the Immersion Grating Infrared Spectrograph. Previous studies indicate that the region around LkHα 234 is complex, with several embedded young stellar objects and the outflows associated with them. In simultaneous H- and K-band spectra from HH 167, we detected 5 [Fe ii] and 14 H2 emission lines. We revealed a new [Fe ii] jet driven by radio continuum source VLA 3B. Position–velocity diagrams of the H2 1−0 S(1) λ2.122 μm line show multiple velocity peaks. The kinematics may be explained by a geometrical bow shock model. We detected a component of H2 emission at the systemic velocity (VLSR = −10.2 km s−1) along the whole slit in all slit positions, which may arise from the ambient photodissociation region. Low-velocity gas dominates the molecular hydrogen emission from knots A and B in HH 167, which is close to the systemic velocity; [Fe ii] emission lines are detected farther from the systemic velocity, at VLSR = −100–−130 km s−1. We infer that the H2 emission arises from shocked gas entrained by a high-velocity outflow. Population diagrams of H2 lines imply that the gas is thermalized at a temperature of 2500–3000 K and the emission results from shock excitation. [ABSTRACT FROM AUTHOR]

Published

2016

15. STAR CLUSTER PROPERTIES IN TWO LEGUS GALAXIES COMPUTED WITH STOCHASTIC STELLAR POPULATION SYNTHESIS MODELS.

Author

Mark R. Krumholz, Angela Adamo, Michele Fumagalli, Aida Wofford, Daniela Calzetti, Janice C. Lee, Bradley C. Whitmore, Stacey N. Bright, Kathryn Grasha, Dimitrios A. Gouliermis, Hwihyun Kim, Preethi Nair, Jenna E. Ryon, Linda J. Smith, David Thilker, Leonardo Ubeda, and Erik Zackrisson

Subjects

*STAR clusters, *STOCHASTIC analysis, *STELLAR populations, *BAYESIAN analysis, *ASTRONOMICAL photometry

Abstract

We investigate a novel Bayesian analysis method, based on the Stochastically Lighting Up Galaxies (slug) code, to derive the masses, ages, and extinctions of star clusters from integrated light photometry. Unlike many analysis methods, slug correctly accounts for incomplete initial mass function (IMF) sampling, and returns full posterior probability distributions rather than simply probability maxima. We apply our technique to 621 visually confirmed clusters in two nearby galaxies, NGC 628 and NGC 7793, that are part of the Legacy Extragalactic UV Survey (LEGUS). LEGUS provides Hubble Space Telescope photometry in the NUV, U, B, V, and I bands. We analyze the sensitivity of the derived cluster properties to choices of prior probability distribution, evolutionary tracks, IMF, metallicity, treatment of nebular emission, and extinction curve. We find that slug's results for individual clusters are insensitive to most of these choices, but that the posterior probability distributions we derive are often quite broad, and sometimes multi-peaked and quite sensitive to the choice of priors. In contrast, the properties of the cluster population as a whole are relatively robust against all of these choices. We also compare our results from slug to those derived with a conventional non-stochastic fitting code, Yggdrasil. We show that slug's stochastic models are generally a better fit to the observations than the deterministic ones used by Yggdrasil. However, the overall properties of the cluster populations recovered by both codes are qualitatively similar. [ABSTRACT FROM AUTHOR]

Published

2015