Infrared Photometric Properties of 709 Candidate Stellar Bowshock Nebulae

Arcuate infrared nebulae are ubiquitous throughout the Galactic Plane and are candidates for partial shells, bubbles, or bowshocks produced by massive runaway stars. We tabulate infrared photometry for 709 such objects using images from the Spitzer Space Telescope, the Wide-field Infrared Explorer,...

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Veröffentlicht in:	The Astronomical journal 2017-11, Vol.154 (5), p.201
Hauptverfasser:	Kobulnicky, Henry A., Schurhammer, Danielle P., Baldwin, Daniel J., Chick, William T., Dixon, Don M., Lee, Daniel, Povich, Matthew S.
Format:	Artikel
Sprache:	eng
Schlagworte:	Aromatic hydrocarbons Astronomy ASTROPHYSICS, COSMOLOGY AND ASTRONOMY Bandpass BRIGHTNESS Color Color temperature COSMIC DUST DISTANCE Dust ENERGY DENSITY ENERGY SPECTRA Environment models Flux density H2 REGIONS HII regions Infrared photometry Infrared telescopes Interstellar dust Interstellar matter ISM: bubbles LUMINOSITY Massive stars NEBULAE Object recognition PHOTOMETRY POLYCYCLIC AROMATIC HYDROCARBONS Radiation Radiative equilibrium SPACE Space telescopes STARS stars: massive STEADY-STATE CONDITIONS STELLAR WINDS SURFACES surveys TELESCOPES
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description	Arcuate infrared nebulae are ubiquitous throughout the Galactic Plane and are candidates for partial shells, bubbles, or bowshocks produced by massive runaway stars. We tabulate infrared photometry for 709 such objects using images from the Spitzer Space Telescope, the Wide-field Infrared Explorer, and the Herschel Space Observatory (HSO). Of the 709 objects identified at 24 or 22 m, 422 are detected at the HSO 70 m bandpass. Of these, only 39 are detected at HSO 160 m. The 70 m peak surface brightnesses are 0.5-2.5 Jy arcmin−2. Color temperatures calculated from the 24 to 70 m ratios range from 80 to 400 K. Color temperatures from 70 to 160 m ratios are systematically lower, 40-200 K. Both of these temperature are, on average, 75% higher than the nominal temperatures derived by assuming that dust is in steady-state radiative equilibrium. This may be evidence of stellar wind bowshocks sweeping up and heating-possibly fragmenting but not destroying-interstellar dust. Infrared luminosity correlates with standoff distance, R0, as predicted by published hydrodynamical models. Infrared spectral energy distributions are consistent with interstellar dust exposed to either single radiant energy density, (in more than half of the objects) or a range of radiant energy densities Umin = 25 to Umax = 103-105 times the mean interstellar value for the remainder. Hence, the central OB stars dominate the energetics, making these enticing laboratories for testing dust models in constrained radiation environments. The spectral energy densities are consistent with polycyclic aromatic hydrocarbon fractions in most objects.
doi_str_mv	10.3847/1538-3881/aa90ba
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We tabulate infrared photometry for 709 such objects using images from the Spitzer Space Telescope, the Wide-field Infrared Explorer, and the Herschel Space Observatory (HSO). Of the 709 objects identified at 24 or 22 m, 422 are detected at the HSO 70 m bandpass. Of these, only 39 are detected at HSO 160 m. The 70 m peak surface brightnesses are 0.5-2.5 Jy arcmin−2. Color temperatures calculated from the 24 to 70 m ratios range from 80 to 400 K. Color temperatures from 70 to 160 m ratios are systematically lower, 40-200 K. Both of these temperature are, on average, 75% higher than the nominal temperatures derived by assuming that dust is in steady-state radiative equilibrium. This may be evidence of stellar wind bowshocks sweeping up and heating-possibly fragmenting but not destroying-interstellar dust. Infrared luminosity correlates with standoff distance, R0, as predicted by published hydrodynamical models. Infrared spectral energy distributions are consistent with interstellar dust exposed to either single radiant energy density, (in more than half of the objects) or a range of radiant energy densities Umin = 25 to Umax = 103-105 times the mean interstellar value for the remainder. Hence, the central OB stars dominate the energetics, making these enticing laboratories for testing dust models in constrained radiation environments. 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J</addtitle><description>Arcuate infrared nebulae are ubiquitous throughout the Galactic Plane and are candidates for partial shells, bubbles, or bowshocks produced by massive runaway stars. We tabulate infrared photometry for 709 such objects using images from the Spitzer Space Telescope, the Wide-field Infrared Explorer, and the Herschel Space Observatory (HSO). Of the 709 objects identified at 24 or 22 m, 422 are detected at the HSO 70 m bandpass. Of these, only 39 are detected at HSO 160 m. The 70 m peak surface brightnesses are 0.5-2.5 Jy arcmin−2. Color temperatures calculated from the 24 to 70 m ratios range from 80 to 400 K. Color temperatures from 70 to 160 m ratios are systematically lower, 40-200 K. Both of these temperature are, on average, 75% higher than the nominal temperatures derived by assuming that dust is in steady-state radiative equilibrium. This may be evidence of stellar wind bowshocks sweeping up and heating-possibly fragmenting but not destroying-interstellar dust. Infrared luminosity correlates with standoff distance, R0, as predicted by published hydrodynamical models. Infrared spectral energy distributions are consistent with interstellar dust exposed to either single radiant energy density, (in more than half of the objects) or a range of radiant energy densities Umin = 25 to Umax = 103-105 times the mean interstellar value for the remainder. Hence, the central OB stars dominate the energetics, making these enticing laboratories for testing dust models in constrained radiation environments. The spectral energy densities are consistent with polycyclic aromatic hydrocarbon fractions in most objects.</description><subject>Aromatic hydrocarbons</subject><subject>Astronomy</subject><subject>ASTROPHYSICS, COSMOLOGY AND ASTRONOMY</subject><subject>Bandpass</subject><subject>BRIGHTNESS</subject><subject>Color</subject><subject>Color temperature</subject><subject>COSMIC DUST</subject><subject>DISTANCE</subject><subject>Dust</subject><subject>ENERGY DENSITY</subject><subject>ENERGY SPECTRA</subject><subject>Environment models</subject><subject>Flux density</subject><subject>H2 REGIONS</subject><subject>HII regions</subject><subject>Infrared photometry</subject><subject>Infrared telescopes</subject><subject>Interstellar dust</subject><subject>Interstellar matter</subject><subject>ISM: bubbles</subject><subject>LUMINOSITY</subject><subject>Massive stars</subject><subject>NEBULAE</subject><subject>Object recognition</subject><subject>PHOTOMETRY</subject><subject>POLYCYCLIC AROMATIC HYDROCARBONS</subject><subject>Radiation</subject><subject>Radiative equilibrium</subject><subject>SPACE</subject><subject>Space telescopes</subject><subject>STARS</subject><subject>stars: massive</subject><subject>STEADY-STATE CONDITIONS</subject><subject>STELLAR WINDS</subject><subject>SURFACES</subject><subject>surveys</subject><subject>TELESCOPES</subject><issn>0004-6256</issn><issn>1538-3881</issn><issn>1538-3881</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><recordid>eNp1kEFrGzEQRkVpoa6be48LzTFbj1bSrnRsTJIaTGJIchZj7Qiva682kkzIv88al_rSngaG930zPMa-cfghtGxmXAldCq35DNHAGj-wyd_VRzYBAFnWlao_sy8pbQE41yAnbLHofcRIbbHahBz2lGPnilUMA8XcUSqCLxowxRz7tmsxU_GYabfDWFyH17QJ7ndxT-vDDukr--Rxl-jiz5yy59ubp_mvcvlwt5j_XJZOQpNLQsNV23pHtBZgjKhE7b1Sijxo3tQSnMFaNiAQBfeAql0b34jWKV0ZFGLKvp96Q8qdTa7L5DYu9D25bKtK1wI4nKkhhpcDpWy34RD78TE7HlS1ro2UIwUnysWQUiRvh9jtMb5ZDvao1R4d2qNDe9I6Ri5PkS4M507cjqS0ylbA7dD6Ebv6B_bf1neqn4P-</recordid><startdate>20171101</startdate><enddate>20171101</enddate><creator>Kobulnicky, Henry A.</creator><creator>Schurhammer, Danielle P.</creator><creator>Baldwin, Daniel J.</creator><creator>Chick, William T.</creator><creator>Dixon, Don M.</creator><creator>Lee, Daniel</creator><creator>Povich, Matthew S.</creator><general>The American Astronomical Society</general><general>IOP Publishing</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TG</scope><scope>8FD</scope><scope>H8D</scope><scope>KL.</scope><scope>L7M</scope><scope>OTOTI</scope><orcidid>https://orcid.org/0000-0001-9062-3583</orcidid><orcidid>https://orcid.org/0000-0002-4475-4176</orcidid></search><sort><creationdate>20171101</creationdate><title>Infrared Photometric Properties of 709 Candidate Stellar Bowshock Nebulae</title><author>Kobulnicky, Henry A. ; 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J</addtitle><date>2017-11-01</date><risdate>2017</risdate><volume>154</volume><issue>5</issue><spage>201</spage><pages>201-</pages><issn>0004-6256</issn><issn>1538-3881</issn><eissn>1538-3881</eissn><abstract>Arcuate infrared nebulae are ubiquitous throughout the Galactic Plane and are candidates for partial shells, bubbles, or bowshocks produced by massive runaway stars. We tabulate infrared photometry for 709 such objects using images from the Spitzer Space Telescope, the Wide-field Infrared Explorer, and the Herschel Space Observatory (HSO). Of the 709 objects identified at 24 or 22 m, 422 are detected at the HSO 70 m bandpass. Of these, only 39 are detected at HSO 160 m. The 70 m peak surface brightnesses are 0.5-2.5 Jy arcmin−2. Color temperatures calculated from the 24 to 70 m ratios range from 80 to 400 K. Color temperatures from 70 to 160 m ratios are systematically lower, 40-200 K. Both of these temperature are, on average, 75% higher than the nominal temperatures derived by assuming that dust is in steady-state radiative equilibrium. This may be evidence of stellar wind bowshocks sweeping up and heating-possibly fragmenting but not destroying-interstellar dust. Infrared luminosity correlates with standoff distance, R0, as predicted by published hydrodynamical models. Infrared spectral energy distributions are consistent with interstellar dust exposed to either single radiant energy density, (in more than half of the objects) or a range of radiant energy densities Umin = 25 to Umax = 103-105 times the mean interstellar value for the remainder. Hence, the central OB stars dominate the energetics, making these enticing laboratories for testing dust models in constrained radiation environments. 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subjects	Aromatic hydrocarbons Astronomy ASTROPHYSICS, COSMOLOGY AND ASTRONOMY Bandpass BRIGHTNESS Color Color temperature COSMIC DUST DISTANCE Dust ENERGY DENSITY ENERGY SPECTRA Environment models Flux density H2 REGIONS HII regions Infrared photometry Infrared telescopes Interstellar dust Interstellar matter ISM: bubbles LUMINOSITY Massive stars NEBULAE Object recognition PHOTOMETRY POLYCYCLIC AROMATIC HYDROCARBONS Radiation Radiative equilibrium SPACE Space telescopes STARS stars: massive STEADY-STATE CONDITIONS STELLAR WINDS SURFACES surveys TELESCOPES
title	Infrared Photometric Properties of 709 Candidate Stellar Bowshock Nebulae
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