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Interstellar Isomers: The Importance of Bonding Energy Differences
We present strong detections of methyl cyanide (CH sub(3)CN), vinyl cyanide (CH sub(2)CHCN), ethyl cyanide (CH sub(3)CH sub(2)CN), and cyanodiacetylene (HC sub(4)CN) molecules with the Green Bank Telescope (GBT) toward the Sgr B2(N) molecular cloud. Attempts to detect the corresponding isocyanide is...
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| Published in: | The Astrophysical journal 2005-10, Vol.632 (1), p.333-339 |
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| container_title | The Astrophysical journal |
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| creator | Remijan, Anthony J Hollis, J. M Lovas, F. J Plusquellic, D. F Jewell, P. R |
| description | We present strong detections of methyl cyanide (CH sub(3)CN), vinyl cyanide (CH sub(2)CHCN), ethyl cyanide (CH sub(3)CH sub(2)CN), and cyanodiacetylene (HC sub(4)CN) molecules with the Green Bank Telescope (GBT) toward the Sgr B2(N) molecular cloud. Attempts to detect the corresponding isocyanide isomers were only successful in the case of methyl isocyanide (CH sub(3)NC) for its J sub(K) = 1 sub(0)-0 sub(0) transition, which is the first interstellar report of this line. To determine the spatial distribution of CH sub(3)NC, we used archival Berkeley-Illinois-Maryland Association (BIMA) array data for the J sub(K) = 4 sub(K)-3 sub(K) (K = 0-3) transitions, but no emission was detected. From ab initio calculations, the bonding energy difference between the cyanide and isocyanide molecules is >8500 cm super(-1) (>12,000 K). Thus, cyanides are the more stable isomers and would likely be formed more preferentially over their isocyanide counterparts. That we detect CH sub(3)NC emission with a single antenna (Gaussian beam size sub(B) = 1723 arcsec super(2)) but not with an interferometer ( sub(B) = 192 arcsec super(2)) strongly suggests that CH sub(3)NC has a widespread spatial distribution toward the Sgr B2(N) region. Other investigators have shown that CH sub(3)CN is present both in the LMH hot core of Sgr B2(N) and in the surrounding medium, while we have shown that CH sub(3)NC appears to be deficient in the LMH hot core. Thus, large-scale, nonthermal processes in the surrounding medium may account for the conversion of CH sub(3)CN to CH sub(3)NC, while the LMH hot core, which is dominated by thermal processes, does not produce a significant amount of CH sub(3)NC. Ice analog experiments by other investigators have shown that radiation bombardment of CH sub(3)CN can produce CH sub(3)NC, thus supporting our observations. We conclude that isomers separated by such large bonding energy differences are distributed in different interstellar environments, making the evaluation of column density ratios between such isomers irrelevant unless it can be independently shown that these species are cospatial. |
| doi_str_mv | 10.1086/432908 |
| format | article |
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M ; Lovas, F. J ; Plusquellic, D. F ; Jewell, P. R</creator><creatorcontrib>Remijan, Anthony J ; Hollis, J. M ; Lovas, F. J ; Plusquellic, D. F ; Jewell, P. R</creatorcontrib><description>We present strong detections of methyl cyanide (CH sub(3)CN), vinyl cyanide (CH sub(2)CHCN), ethyl cyanide (CH sub(3)CH sub(2)CN), and cyanodiacetylene (HC sub(4)CN) molecules with the Green Bank Telescope (GBT) toward the Sgr B2(N) molecular cloud. Attempts to detect the corresponding isocyanide isomers were only successful in the case of methyl isocyanide (CH sub(3)NC) for its J sub(K) = 1 sub(0)-0 sub(0) transition, which is the first interstellar report of this line. To determine the spatial distribution of CH sub(3)NC, we used archival Berkeley-Illinois-Maryland Association (BIMA) array data for the J sub(K) = 4 sub(K)-3 sub(K) (K = 0-3) transitions, but no emission was detected. From ab initio calculations, the bonding energy difference between the cyanide and isocyanide molecules is >8500 cm super(-1) (>12,000 K). Thus, cyanides are the more stable isomers and would likely be formed more preferentially over their isocyanide counterparts. That we detect CH sub(3)NC emission with a single antenna (Gaussian beam size sub(B) = 1723 arcsec super(2)) but not with an interferometer ( sub(B) = 192 arcsec super(2)) strongly suggests that CH sub(3)NC has a widespread spatial distribution toward the Sgr B2(N) region. Other investigators have shown that CH sub(3)CN is present both in the LMH hot core of Sgr B2(N) and in the surrounding medium, while we have shown that CH sub(3)NC appears to be deficient in the LMH hot core. Thus, large-scale, nonthermal processes in the surrounding medium may account for the conversion of CH sub(3)CN to CH sub(3)NC, while the LMH hot core, which is dominated by thermal processes, does not produce a significant amount of CH sub(3)NC. Ice analog experiments by other investigators have shown that radiation bombardment of CH sub(3)CN can produce CH sub(3)NC, thus supporting our observations. 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M</creatorcontrib><creatorcontrib>Lovas, F. J</creatorcontrib><creatorcontrib>Plusquellic, D. F</creatorcontrib><creatorcontrib>Jewell, P. R</creatorcontrib><title>Interstellar Isomers: The Importance of Bonding Energy Differences</title><title>The Astrophysical journal</title><description>We present strong detections of methyl cyanide (CH sub(3)CN), vinyl cyanide (CH sub(2)CHCN), ethyl cyanide (CH sub(3)CH sub(2)CN), and cyanodiacetylene (HC sub(4)CN) molecules with the Green Bank Telescope (GBT) toward the Sgr B2(N) molecular cloud. Attempts to detect the corresponding isocyanide isomers were only successful in the case of methyl isocyanide (CH sub(3)NC) for its J sub(K) = 1 sub(0)-0 sub(0) transition, which is the first interstellar report of this line. To determine the spatial distribution of CH sub(3)NC, we used archival Berkeley-Illinois-Maryland Association (BIMA) array data for the J sub(K) = 4 sub(K)-3 sub(K) (K = 0-3) transitions, but no emission was detected. From ab initio calculations, the bonding energy difference between the cyanide and isocyanide molecules is >8500 cm super(-1) (>12,000 K). Thus, cyanides are the more stable isomers and would likely be formed more preferentially over their isocyanide counterparts. That we detect CH sub(3)NC emission with a single antenna (Gaussian beam size sub(B) = 1723 arcsec super(2)) but not with an interferometer ( sub(B) = 192 arcsec super(2)) strongly suggests that CH sub(3)NC has a widespread spatial distribution toward the Sgr B2(N) region. Other investigators have shown that CH sub(3)CN is present both in the LMH hot core of Sgr B2(N) and in the surrounding medium, while we have shown that CH sub(3)NC appears to be deficient in the LMH hot core. Thus, large-scale, nonthermal processes in the surrounding medium may account for the conversion of CH sub(3)CN to CH sub(3)NC, while the LMH hot core, which is dominated by thermal processes, does not produce a significant amount of CH sub(3)NC. Ice analog experiments by other investigators have shown that radiation bombardment of CH sub(3)CN can produce CH sub(3)NC, thus supporting our observations. We conclude that isomers separated by such large bonding energy differences are distributed in different interstellar environments, making the evaluation of column density ratios between such isomers irrelevant unless it can be independently shown that these species are cospatial.</description><subject>Astronomy</subject><subject>Earth, ocean, space</subject><subject>Exact sciences and technology</subject><issn>0004-637X</issn><issn>1538-4357</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2005</creationdate><recordtype>article</recordtype><recordid>eNp90UFLwzAYBuAgCs6pv6EeVBCqSZM2jTc3pxYGXiZ4C2n6ZVbapibdYf_elA08iF4SPvLwEt4PoXOCbwnOsztGE4HzAzQhKc1jRlN-iCYYYxZnlL8foxPvP8cxEWKCZkU3gPMDNI1yUeFtG6b7aPUBUdH21g2q0xBZE81sV9XdOlp04Nbb6LE2BhyER3-KjoxqPJzt7yl6e1qs5i_x8vW5mD8sY82wGGIuqCo50arEVFeKVSbDwIxRSmdlluZlmWmhc1FVqQHglAQLIiFQ6kpnStMput7l9s5-bcAPsq29Hj_egd14yRmlqcBCBHn1rySc5URg8gO1s947MLJ3davcVhIsxzLlrswAL_eJymvVGBdqqf2P5klOQ9PBXexcbfu_s25-m3EhctxPOBJJJKVU9pWh38JMi0s</recordid><startdate>20051010</startdate><enddate>20051010</enddate><creator>Remijan, Anthony J</creator><creator>Hollis, J. 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R</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c409t-793ab71cab03cda4df60e4ffaac6b658bb6c9c89dd5fee73171ce921ebcdc6ac3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2005</creationdate><topic>Astronomy</topic><topic>Earth, ocean, space</topic><topic>Exact sciences and technology</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Remijan, Anthony J</creatorcontrib><creatorcontrib>Hollis, J. M</creatorcontrib><creatorcontrib>Lovas, F. J</creatorcontrib><creatorcontrib>Plusquellic, D. F</creatorcontrib><creatorcontrib>Jewell, P. 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R</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Interstellar Isomers: The Importance of Bonding Energy Differences</atitle><jtitle>The Astrophysical journal</jtitle><date>2005-10-10</date><risdate>2005</risdate><volume>632</volume><issue>1</issue><spage>333</spage><epage>339</epage><pages>333-339</pages><issn>0004-637X</issn><eissn>1538-4357</eissn><coden>ASJOAB</coden><abstract>We present strong detections of methyl cyanide (CH sub(3)CN), vinyl cyanide (CH sub(2)CHCN), ethyl cyanide (CH sub(3)CH sub(2)CN), and cyanodiacetylene (HC sub(4)CN) molecules with the Green Bank Telescope (GBT) toward the Sgr B2(N) molecular cloud. Attempts to detect the corresponding isocyanide isomers were only successful in the case of methyl isocyanide (CH sub(3)NC) for its J sub(K) = 1 sub(0)-0 sub(0) transition, which is the first interstellar report of this line. To determine the spatial distribution of CH sub(3)NC, we used archival Berkeley-Illinois-Maryland Association (BIMA) array data for the J sub(K) = 4 sub(K)-3 sub(K) (K = 0-3) transitions, but no emission was detected. From ab initio calculations, the bonding energy difference between the cyanide and isocyanide molecules is >8500 cm super(-1) (>12,000 K). Thus, cyanides are the more stable isomers and would likely be formed more preferentially over their isocyanide counterparts. That we detect CH sub(3)NC emission with a single antenna (Gaussian beam size sub(B) = 1723 arcsec super(2)) but not with an interferometer ( sub(B) = 192 arcsec super(2)) strongly suggests that CH sub(3)NC has a widespread spatial distribution toward the Sgr B2(N) region. Other investigators have shown that CH sub(3)CN is present both in the LMH hot core of Sgr B2(N) and in the surrounding medium, while we have shown that CH sub(3)NC appears to be deficient in the LMH hot core. Thus, large-scale, nonthermal processes in the surrounding medium may account for the conversion of CH sub(3)CN to CH sub(3)NC, while the LMH hot core, which is dominated by thermal processes, does not produce a significant amount of CH sub(3)NC. Ice analog experiments by other investigators have shown that radiation bombardment of CH sub(3)CN can produce CH sub(3)NC, thus supporting our observations. We conclude that isomers separated by such large bonding energy differences are distributed in different interstellar environments, making the evaluation of column density ratios between such isomers irrelevant unless it can be independently shown that these species are cospatial.</abstract><cop>Chicago, IL</cop><pub>IOP Publishing</pub><doi>10.1086/432908</doi><tpages>7</tpages><oa>free_for_read</oa></addata></record> |
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| subjects | Astronomy Earth, ocean, space Exact sciences and technology |
| title | Interstellar Isomers: The Importance of Bonding Energy Differences |
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