Your search keyword '"Marc W. Pound"' showing total 3 results

1. SOFIA FEEDBACK Survey: The Pillars of Creation in [C ii] and Molecular Lines

Author

Ramsey L. Karim, Marc W. Pound, Alexander G. G. M. Tielens, Maitraiyee Tiwari, Lars Bonne, Mark G. Wolfire, Nicola Schneider, Ümit Kavak, Lee G. Mundy, Robert Simon, Rolf Güsten, Jürgen Stutzki, Friedrich Wyrowski, and Netty Honingh

Subjects

Photodissociation regions, Interstellar clouds, Stellar feedback, Astronomy, QB1-991

Abstract

We investigate the physical structure and conditions of photodissociation regions (PDRs) and molecular gas within the Pillars of Creation in the Eagle Nebula using SOFIA FEEDBACK observations of the [C ii ] 158 μ m line. These observations are velocity resolved to 0.5 km s ^−1 and are analyzed alongside a collection of complimentary data with similar spatial and spectral resolution: the [O i ] 63 μ m line, also observed with SOFIA, and rotational lines of CO, HCN, HCO ^+ , CS, and N _2 H ^+ . Using the superb spectral resolution of SOFIA, APEX, CARMA, and BIMA, we reveal the relationships between the warm PDR and cool molecular gas layers in context of the Pillars’ kinematic structure. We assemble a geometric picture of the Pillars and their surroundings informed by illumination patterns and kinematic relationships and derive physical conditions in the PDRs associated with the Pillars. We estimate an average molecular gas density ${n}_{{{\rm{H}}}_{2}}\sim 1.3\,\times \,{10}^{5}$ cm ^−3 and an average atomic gas density n _H ∼ 1.8 × 10 ^4 cm ^−3 and infer that the ionized, atomic, and molecular phases are in pressure equilibrium if the atomic gas is magnetically supported. We find pillar masses of 103, 78, 103, and 18 M _⊙ for P1a, P1b, P2, and P3, respectively, and evaporation times of ∼1–2 Myr. The dense clumps at the tops of the pillars are currently supported by the magnetic field. Our analysis suggests that ambipolar diffusion is rapid and these clumps are likely to collapse within their photoevaporation timescales.

Published

2023

2. The PhotoDissociation Region Toolbox: Software and Models for Astrophysical Analysis

Author

Marc W. Pound and Mark G. Wolfire

Subjects

Photodissociation regions, Astronomy software, Molecular gas, Interstellar atomic gas, Astronomy, QB1-991

Abstract

The PhotoDissociation Region Toolbox provides comprehensive, easy-to-use, public software tools and models that enable an understanding of the interaction of the light of young, luminous, massive stars with the gas and dust in the Milky Way and in other galaxies. It consists of an open-source Python toolkit and photodissociation region (PDR) models for analysis of infrared and millimeter/submillimeter line and continuum observations obtained by ground-based and suborbital telescopes, and astrophysics space missions. PDRs include all of the neutral gas in the interstellar medium where far-ultraviolet photons dominate the chemistry and/or heating. In regions of massive star formation, PDRs are created at the boundaries between the H ii regions and neutral molecular cloud, as photons with energies 6 eV < h ν < 13.6 eV photodissociate molecules and photoionize metals. The gas is heated by photoelectrons from small grains and large molecules and cools mostly through far-infrared (FIR) fine-structure lines like [O i ] and [C ii ]. The models are created from state-of-the art PDR codes that include molecular freeze-out; recent collision, chemical, and photorates; new chemical pathways, such as oxygen chemistry; and allow for both clumpy and uniform media. The models predict the emergent intensities of many spectral lines and FIR continuum. The tools find the best-fit models to the observations and provide insight into the physical conditions and chemical makeup of the gas and dust. The PDR Toolbox enables novel analysis of data from telescopes such as the Infrared Space Observatory, Spitzer, Herschel, the Stratospheric Terahertz Observatory, the Stratospheric Observatory for Infrared Astronomy, the Submillimeter Wave Astronomy Satellite, the Atacama Pathfinder Experiment, the Atacama Large Millimeter/submillimeter Array, and the JWST.

Published

2022

3. THE CARMA PAIRED ANTENNA CALIBRATION SYSTEM: ATMOSPHERIC PHASE CORRECTION FOR MILLIMETER WAVE INTERFEROMETRY AND ITS APPLICATION TO MAPPING THE ULTRALUMINOUS GALAXY ARP 193.

Author

B. Ashley Zauderer, Alberto D. Bolatto, Stuart N. Vogel, John M. Carpenter, Laura M. Peréz, James W. Lamb, David P. Woody, Douglas C.-J. Bock, John E. Carlstrom, Thomas L. Culverhouse, Roger Curley, Erik M. Leitch, Richard L. Plambeck, Marc W. Pound, Daniel P. Marrone, Stephen J. Muchovej, Lee G. Mundy, Stacy H. Teng, Peter J. Teuben, and Nikolaus H. Volgenau

Published

2016