Your search keyword '"Dan P. Clemens"' showing total 11 results

1. Magnetic Fields of the Starless Core L 1512

Author

Sheng-Jun Lin, Shih-Ping Lai, Kate Pattle, David Berry, Dan P. Clemens, Laurent Pagani, Derek Ward-Thompson, Travis J. Thieme, and Tao-Chung Ching

Subjects

Interstellar magnetic fields, Interstellar medium, Molecular clouds, Polarimetry, Submillimeter astronomy, Star forming regions, Astrophysics, QB460-466

Abstract

We present JCMT POL-2 850 μ m dust polarization observations and Mimir H -band stellar polarization observations toward the starless core L 1512. We detect the highly ordered core-scale magnetic field traced by the POL-2 data, of which the field orientation is consistent with the parsec-scale magnetic fields traced by Planck data, suggesting the large-scale fields thread from the low-density region to the dense core region in this cloud. The surrounding magnetic field traced by the Mimir data shows a wider variation in the field orientation, suggesting there could be a transition of magnetic field morphology at the envelope-scale. L 1512 was suggested to be presumably older than 1.4 Myr in a previous study via time-dependent chemical analysis, hinting that the magnetic field could be strong enough to slow the collapse of L 1512. In this study, we use the Davis–Chandrasekhar–Fermi method to derive a plane-of-sky magnetic field strength ( B _pos ) of 18 ± 7 μ G and an observed mass-to-flux ratio ( λ _obs ) of 3.5 ± 2.4, suggesting that L 1512 is magnetically supercritical. However, the absence of significant infall motion and the presence of an oscillating envelope are inconsistent with the magnetically supercritical condition. Using a virial analysis, we suggest the presence of a hitherto hidden line-of-sight magnetic field strength of ∼27 μ G with a mass-to-flux ratio ( λ _tot ) of ∼1.6, in which case both magnetic and kinetic pressures are important in supporting the L 1512 core. On the other hand, L 1512 may have just reached supercriticality and will collapse at any time.

Published

2024

2. 'Spectral Energy Distributions of Be and Other Massive Stars' ( PASP, 122, 379, [2010] )

Author

Y. Touhami, M. V. McSwain, Tabetha S. Boyajian, Brian W. Taylor, Douglas R. Gies, Noel D. Richardson, Erika D. Grundstrom, Dan P. Clemens, Stephen J. Williams, and Gail Schaefer

Subjects

Physics, Stars, Space and Planetary Science, Spectral density, Astronomy, Astronomy and Astrophysics, Astrophysics

Published

2012

3. Spectral Energy Distributions of Be and Other Massive Stars

Author

Y. Touhami, Erika D. Grundstrom, D. R. Gies, N. D. Richardson, Gail Schaefer, Stephen J. Williams, Brian Taylor, M. V. McSwain, Tabetha S. Boyajian, and Dan P. Clemens

Subjects

010504 meteorology & atmospheric sciences, Hydrogen, Be star, media_common.quotation_subject, FOS: Physical sciences, chemistry.chemical_element, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics, 01 natural sciences, Flux (metallurgy), 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Emission spectrum, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences, media_common, Physics, Spectral density, Astronomy and Astrophysics, Stars, Interferometry, Astrophysics - Solar and Stellar Astrophysics, chemistry, 13. Climate action, Space and Planetary Science, Sky, Astrophysics::Earth and Planetary Astrophysics

Abstract

We present spectrophotometric data from 0.4 to 4.2 microns for bright, northern sky, Be stars and several other types of massive stars. Our goal is to use these data with ongoing, high angular resolution, interferometric observations to model the density structure and sky orientation of the gas surrounding these stars. We also present a montage of the H-alpha and near-infrared emission lines that form in Be star disks. We find that a simplified measurement of the IR excess flux appears to be correlated with the strength of emission lines from high level transitions of hydrogen. This suggests that the near-IR continuum and upper level line fluxes both form in the inner part of the disk, close to the star., 2010, PASP, 122, 379

Published

2010

4. Mimir: A Near-Infrared Wide-Field Imager, Spectrometer, and Polarimeter

Author

Brian W. Taylor, Eric V. Tollestrup, D. Sarcia, A. Grabau, Marc W. Buie, Dan P. Clemens, and Edward W. Dunham

Subjects

Physics, Spectrometer, business.industry, Near-infrared spectroscopy, Detector, Polarimetry, Astronomy and Astrophysics, Field of view, Collimator, Polarimeter, law.invention, Telescope, Optics, Space and Planetary Science, law, business

Abstract

Mimir, a new facility-class near-infrared instrument for the 1.8 m Perkins telescope on Anderson Mesa outside Flagstaff, Arizona, was commissioned and has been operating for three years. Mimir is multifunction, performing wide-field (F=5) and narrow-field (F=17) imaging, long-slit spectroscopy, and imaging polarimetry. The F=5 mode images at 0.59" per pixel onto the 1024 × 1024 pixel ALADDIN III InSb array detector, giving a 10 0 × 10 0 field of view. In the F=17 mode, the plate scale is 0.18" per pixel. Optically, Mimir is a refractive reimager for the F=17:5 Perkins beam. A six-lens collimator produces an achromatic 25 mm pupil, which is imaged by a five-lens camera (F=5), a four-lens camera (F=17), or a two-lens pupil viewer onto the detector. Three filter wheels precede the pupil, one follows the pupil. The wheels contain a rotating half-wave plate, broadband filters, narrowband filters, grisms, long-pass filters, a wire grid, and thermal IR blockers. The first telescope focus is within Mimir, where a slit and decker unit, consisting of two linear motion cars, selects one of 13 slit scenes. The slit and decker cars, the four filter wheels, the half-wave plate rotation, and the camera selector are all driven by stepper motors within the cold vacuum space. Cooling is provided by a CTI 1050 two-stage, closed-cycle helium refrigerator, keeping the optics, filters, and internal surfaces between 65 and 75 K and the detector at 33.5 K. Switching between Mimir's different modes takes only a few seconds, making it a versatile tool for conducting a wide range of investigations and for quickly reacting to changing observing conditions. Mimir on the Perkins telescope achieves imaging sensitivities 2-4 mag deeper than 2MASS, moderate resolution (R ∼ 700) JHK spectra of virtually any 2MASS source, high- precision wide-field imaging polarimetry, and L 0 and M 0 band imaging and spectroscopy.

Published

2007

5. Millipol, a millimeter/submillimeter wavelength polarimeter - Instrument, operation, and calibration

Author

Robert W. Leach, Brian D. Kane, Dan P. Clemens, and Richard Barvainis

Subjects

Physics, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Polarimetry, Astronomy, Astronomy and Astrophysics, Polarimeter, Astrophysics::Cosmology and Extragalactic Astrophysics, Polarization (waves), Lunar limb, law.invention, Telescope, Wavelength, Optics, Space and Planetary Science, law, Measuring instrument, Millimeter, Astrophysics::Earth and Planetary Astrophysics, business, Astrophysics::Galaxy Astrophysics

Abstract

An instrument capable of measuring the polarization characteristics of weakly polarized, cold dust at millimeter and submillimeter wavelengths is presented in detail. The operation and calibration of this polarimeter at a wavelength of 1300 microns, configured for the NRAO 12-meter telescope, are discussed. Deep observations of Jupiter using this instrument revealed a main-beam instrumental polarization at, or below, the 0.2 percent level. Lunar limb observations revealed a sidelobe polarization sensitivity, in the range 0.25 percent - 1.0 percent. Further, through these efforts the nonthermal polarized flux from Jupiter at a level of about 0.04 percent of the thermal flux has been detected. Astronomical polarization measurements to 0.03 percent are possible, limited by the uncertainties in the instrumental polarization. This instrument has been primarily employed to measure and map magnetic-field directions in the very optically opaque cores of massive molecular clouds.

Published

1990

6. Multiwavelength Polarimetry of the Filamentary Cloud IC 5146. II. Magnetic Field Structures.

Author

Jia-Wei Wang, Shih-Ping Lai, Dan P. Clemens, Patrick M. Koch, Chakali Eswaraiah, Wen-Ping Chen, and Anil K. Pandey

Subjects

MAGNETIC structure, MAGNETIC fields, MAGNETIC flux density, STELLAR magnetic fields, STAR formation, POLARIMETRY, OPTICAL polarization

Abstract

The IC 5146 cloud is a nearby star-forming region in Cygnus, consisting of molecular gas filaments in a variety of evolutionary stages. We used optical and near-infrared polarization data toward the IC 5146 cloud, reported in the first paper of this series, to reveal the magnetic fields in this cloud. Using the newly released Gaia data, we found that the IC 5146 cloud may contain two separate clouds: a first cloud, including the densest main filament at a distance of ∼600 pc, and a second cloud, associated with the Cocoon Nebula at a distance of ∼800 pc. The spatially averaged H-band polarization map revealed a well-ordered magnetic field morphology, with the polarization segments perpendicular to the main filament but parallel to the nearby subfilaments, consistent with models assuming that the magnetic field is regulating cloud evolution. We estimated the magnetic field strength using the Davis–Chandrasekhar–Fermi method and found that the magnetic field strength scales with volume density with a power-law index of ∼0.5 in the density range from to 3000 cm−3, which indicates an anisotropic cloud contraction with a preferred direction along the magnetic field. In addition, the mass-to-flux ratio of the cloud gradually changes from subcritical to supercritical from the cloud envelope to the deep regions. These features are consistent with strong magnetic field star formation models and suggest that the magnetic field is important in regulating the evolution of the IC 5146 cloud. [ABSTRACT FROM AUTHOR]

Published

2020

7. Erratum: “Magnetic Field Uniformity Across the GF 9-2 YSO, L1082C Dense Core, and GF 9 Filamentary Dark Cloud” (2018, ApJ, 867, 79).

Author

Dan P. Clemens, A. M. El Batal, C. Cerny, S. Kressy, G. Schroeder, and T. Pillai

Subjects

*COSMIC magnetic fields, *CLOUDS

Published

2018

8. Magnetic Field Uniformity Across the GF 9-2 YSO, L1082C Dense Core, and GF 9 Filamentary Dark Cloud.

Author

Dan P. Clemens, A. M. El-Batal, C. Cerny, S. Kressy, G. Schroeder, and T. Pillai

Subjects

*MAGNETIC fields, *WAVELENGTHS, *POLARIMETRY, *CRYSTAL whiskers, *NEAR infrared radiation

Abstract

The orientation of the magnetic field (B field) in the filamentary dark cloud GF 9 was traced from the periphery of the cloud into the L1082C dense core that contains the low-mass, low-luminosity Class 0 young stellar object (YSO) GF 9-2 (IRAS 20503+6006). This was done using SOFIA HAWC+ dust thermal emission polarimetry (TEP) at 216 μm in combination with Mimir near-infrared background starlight polarimetry (BSP) conducted in the H band (1.6 μm) and K band (2.2 μm). These observations were augmented with published I-band (0.77 μm) BSP and Planck 850 μm TEP to probe B-field orientations with offset from the YSO in a range spanning 6000 au to 3 pc. No strong B-field orientation change with offset was found, indicating remarkable uniformity of the B-field from the cloud edge to the YSO environs. This finding disagrees with weak-field models of cloud core and YSO formation. The continuity of inferred B-field orientations for both TEP and BSP probes is strong evidence that both are sampling a common B field that uniformly threads the cloud, core, and YSO region. Bayesian analysis of Gaia DR2 stars matched to the Mimir BSP stars finds a distance to GF 9 of 270 ± 10 pc. No strong wavelength dependence of B-field orientation angle was found, contrary to previous claims. [ABSTRACT FROM AUTHOR]

Published

2018

9. Proper Motion of the Faint Star near KIC 8462852 (Boyajian's Star)—Not a Binary System.

Author

Dan P. Clemens, Kush Maheshwari, Roshan Jagani, J. Montgomery, A. M. El Batal, T. G. Ellis, and J. T. Wright

Published

2018

10. Multiwavelength Stellar Polarimetry of the Filamentary Cloud IC5146. I. Dust Properties.

Author

Jia-Wei Wang, Shih-Ping Lai, Chakali Eswaraiah, Dan P. Clemens, Wen-Ping Chen, and Anil K. Pandey

Subjects

STELLAR polarimetry, INTERPLANETARY dust, CLOUDS, COSMIC magnetic fields, WAVELENGTHS

Abstract

We present optical and near-infrared stellar polarization observations toward the dark filamentary clouds associated with IC5146. The data allow us to investigate the dust properties (this paper) and the magnetic field structure (Paper II). A total of 2022 background stars were detected in the Rc, , H, and/or K bands to mag. The ratio of the polarization percentage at different wavelengths provides an estimate of , the wavelength of the peak polarization, which is an indicator of the small-size cutoff of the grain size distribution. The grain size distribution seems to significantly change at mag, where both the average and dispersion of decrease. In addition, we found μm for mag, which is larger than the ∼0.55 μm in the general interstellar medium (ISM), suggesting that grain growth has already started in low-AV regions. Our data also reveal that polarization efficiency () decreases with AV as a power law in the Rc, , and K bands with indices of −0.71 ± 0.10, −1.23 ± 0.10, and −0.53 ± 0.09. However, H-band data show a power index change; the PE varies with AV steeply (index of −0.95 ± 0.30) when mag, but softly (index of −0.25 ± 0.06) for greater AV values. The soft decay of PE in high-AV regions is consistent with the radiative alignment torque model, suggesting that our data trace the magnetic field to mag. Furthermore, the breakpoint found in the H band is similar to that for AV, where we found the dispersion significantly decreased. Therefore, the flat PE–AV in high-AV regions implies that the power-index changes result from additional grain growth. [ABSTRACT FROM AUTHOR]

Published

2017

11. THE MAGNETIC FIELD OF L1544. I. NEAR-INFRARED POLARIMETRY AND THE NON-UNIFORM ENVELOPE.

Author

Dan P. Clemens, K. Tassis, and Paul F. Goldsmith

Subjects

*INTERSTELLAR medium, *POLARIMETRY, *NEAR infrared spectroscopy, *ZEEMAN effect, *MAGNETIC fields, *NEBULAE

Abstract

The magnetic field (B-field) of the starless dark cloud L1544 has been studied using near-infrared (NIR) background starlight polarimetry (BSP) and archival data in order to characterize the properties of the plane-of-sky B-field. NIR linear polarization measurements of over 1700 stars were obtained in the H band and 201 of these were also measured in the K band. The NIR BSP properties are correlated with reddening, as traced using the Rayleigh–Jeans color excess (H–M) method, and with thermal dust emission from the L1544 cloud and envelope seen in Herschel maps. The NIR polarization position angles change at the location of the cloud and exhibit their lowest dispersion there, offering strong evidence that NIR polarization traces the plane-of-sky B-field of L1544. In this paper, the uniformity of the plane-of-sky B-field in the envelope region of L1544 is quantitatively assessed. This allows evaluation of the approach of assuming uniform field geometry when measuring relative mass-to-flux ratios in the cloud envelope and core based on averaging of the radio Zeeman observations in the envelope, as done by Crutcher et al. In L1544, the NIR BSP shows the envelope B-field to be significantly non-uniform and likely not suitable for averaging Zeeman properties without treating intrinsic variations. Deeper analyses of the NIR BSP and related data sets, including estimates of the B-field strength and testing how it varies with position and gas density, are the subjects of later papers in this series. [ABSTRACT FROM AUTHOR]

Published

2016