High-Mass Star Formation. I. The Mass Distribution of Submillimeter Clumps in NGC 7538
We present submillimeter continuum maps at 450 and 850 km of a 12' x 8' region of the NGC 7538 high-mass star-forming region, made using the Submillimeter Common-User Bolometer Array (SCUBA) on the James Clerk Maxwell Telescope. We used an automated clump-finding algorithm to identify 67 c...
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| Veröffentlicht in: | The Astrophysical journal 2005-06, Vol.625 (2), p.891-905 |
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| creator | Reid, Michael A Wilson, Christine D |
| description | We present submillimeter continuum maps at 450 and 850 km of a 12' x 8' region of the NGC 7538 high-mass star-forming region, made using the Submillimeter Common-User Bolometer Array (SCUBA) on the James Clerk Maxwell Telescope. We used an automated clump-finding algorithm to identify 67 clumps in the 450 km image and 77 in the 850 km image. Contrary to previous studies, we find a positive correlation between high spectral index, a, and high submillimeter flux, with the difference being accounted for by different treatments of the error beam. We interpret the higher spectral index at submillimeter peaks as a reflection of elevated dust temperature, particularly when there is an embedded infrared source, although it may also reflect changing dust properties. The clump mass-radius relationship is well fitted by a power law of the form M 8 R super(-x) with x = 1.5-2.1, consistent with theories of turbulently supported clumps. According to our most reliable analysis, the high-mass end (6100-2700 M sub( )) of the submillimeter clump mass function in NGC 7538 follows a Salpeter-like power law with index 2.0 c 0.3. This result agrees well with similar studies of lower mass regions r Oph and Orion B. We interpret the apparent invariance of the shape of the clump mass function over a broad range of parent cloud masses as evidence for the self-similarity of the physical processes that determine it. This result is consistent with models that suggest that turbulent fragmentation, acting at early times, is sufficient to set the clump mass function. |
| doi_str_mv | 10.1086/429790 |
| format | Article |
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We interpret the higher spectral index at submillimeter peaks as a reflection of elevated dust temperature, particularly when there is an embedded infrared source, although it may also reflect changing dust properties. The clump mass-radius relationship is well fitted by a power law of the form M 8 R super(-x) with x = 1.5-2.1, consistent with theories of turbulently supported clumps. According to our most reliable analysis, the high-mass end (6100-2700 M sub( )) of the submillimeter clump mass function in NGC 7538 follows a Salpeter-like power law with index 2.0 c 0.3. This result agrees well with similar studies of lower mass regions r Oph and Orion B. We interpret the apparent invariance of the shape of the clump mass function over a broad range of parent cloud masses as evidence for the self-similarity of the physical processes that determine it. 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The clump mass-radius relationship is well fitted by a power law of the form M 8 R super(-x) with x = 1.5-2.1, consistent with theories of turbulently supported clumps. According to our most reliable analysis, the high-mass end (6100-2700 M sub( )) of the submillimeter clump mass function in NGC 7538 follows a Salpeter-like power law with index 2.0 c 0.3. This result agrees well with similar studies of lower mass regions r Oph and Orion B. We interpret the apparent invariance of the shape of the clump mass function over a broad range of parent cloud masses as evidence for the self-similarity of the physical processes that determine it. 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I. The Mass Distribution of Submillimeter Clumps in NGC 7538</atitle><jtitle>The Astrophysical journal</jtitle><date>2005-06-01</date><risdate>2005</risdate><volume>625</volume><issue>2</issue><spage>891</spage><epage>905</epage><pages>891-905</pages><issn>0004-637X</issn><eissn>1538-4357</eissn><coden>ASJOAB</coden><abstract>We present submillimeter continuum maps at 450 and 850 km of a 12' x 8' region of the NGC 7538 high-mass star-forming region, made using the Submillimeter Common-User Bolometer Array (SCUBA) on the James Clerk Maxwell Telescope. We used an automated clump-finding algorithm to identify 67 clumps in the 450 km image and 77 in the 850 km image. Contrary to previous studies, we find a positive correlation between high spectral index, a, and high submillimeter flux, with the difference being accounted for by different treatments of the error beam. We interpret the higher spectral index at submillimeter peaks as a reflection of elevated dust temperature, particularly when there is an embedded infrared source, although it may also reflect changing dust properties. The clump mass-radius relationship is well fitted by a power law of the form M 8 R super(-x) with x = 1.5-2.1, consistent with theories of turbulently supported clumps. According to our most reliable analysis, the high-mass end (6100-2700 M sub( )) of the submillimeter clump mass function in NGC 7538 follows a Salpeter-like power law with index 2.0 c 0.3. This result agrees well with similar studies of lower mass regions r Oph and Orion B. We interpret the apparent invariance of the shape of the clump mass function over a broad range of parent cloud masses as evidence for the self-similarity of the physical processes that determine it. 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| title | High-Mass Star Formation. I. The Mass Distribution of Submillimeter Clumps in NGC 7538 |
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