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molecules:ism:mecho [2019/04/26 15:23] muellermolecules:ism:mecho [2023/03/06 13:09] (current) mueller
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 **Detection of Acetaldehyde in Sagittarius**\\ **Detection of Acetaldehyde in Sagittarius**\\
 //Molecules in the Galactic Environment// eds. M. A. Gordon and L. E. Snyder, Wiley-Interscience, New York, 181–186 (1973).\\ //Molecules in the Galactic Environment// eds. M. A. Gordon and L. E. Snyder, Wiley-Interscience, New York, 181–186 (1973).\\
-The //a//-type //Q//-branch transition 1<sub>10</sub> – 1<sub>11</sub> near 1065 MHz was detected toward Sagittarius A and Sgr B2.+The //a//-type //Q//-branch transition 1<sub>10</sub> – 1<sub>11</sub> near 1065 MHz was detected toward Sagittarius A and Sgr B2.\\ 
 +\\
  
 Soon thereafter, the observation of the 2<sub>11</sub> – 2<sub>12</sub> transition near 3195 MHz toward Sgr B2 with the Parkes 64 m telescope was reported:\\ Soon thereafter, the observation of the 2<sub>11</sub> – 2<sub>12</sub> transition near 3195 MHz toward Sgr B2 with the Parkes 64 m telescope was reported:\\
 N. Fourikis, M. W. Sinclair, B. J. Robinson, P. D. Godfrey, and R. D. Brown,\\ N. Fourikis, M. W. Sinclair, B. J. Robinson, P. D. Godfrey, and R. D. Brown,\\
-**[[http://adsabs.harvard.edu/abs/1974AuJPh..27..425F|Microwave Emission of the 2<sub>11</sub> → 2<sub>12</sub> Rotational Transition in Interstellar Acetaldehyde]]**\\ +**[[https://ui.adsabs.harvard.edu/abs/1974AuJPh..27..425F|Microwave Emission of the 2<sub>11</sub> → 2<sub>12</sub> Rotational Transition in Interstellar Acetaldehyde]]**\\ 
-//Aust. J. Phys.// **27**, 425–430 (1974).+//Aust. J. Phys.// **27**, 425–430 (1974).\\ 
 +\\
  
 Many more transitions were detected toward hot cores such as Sgr B2 or OMC-1. However, the rotational temperatures were usually quite low (50 K or even considerably lower) and suggest an extended distribution. A fairly recent mapping of the 1<sub>10</sub> – 1<sub>11</sub> transition toward Sgr B2 with the GRMT demonstrates this rather nicely:\\ Many more transitions were detected toward hot cores such as Sgr B2 or OMC-1. However, the rotational temperatures were usually quite low (50 K or even considerably lower) and suggest an extended distribution. A fairly recent mapping of the 1<sub>10</sub> – 1<sub>11</sub> transition toward Sgr B2 with the GRMT demonstrates this rather nicely:\\
 J. N. Chengalur and N. Kanekar,\\ J. N. Chengalur and N. Kanekar,\\
 **[[https://doi.org/10.1051/0004-6361:20030577|Widespread Acetaldehyde near the Galactic Centre]]**\\ **[[https://doi.org/10.1051/0004-6361:20030577|Widespread Acetaldehyde near the Galactic Centre]]**\\
-//Astron. Astrophys.// **403**, L43–L46 (2003).+//Astron. Astrophys.// **403**, L43–L46 (2003).\\ 
 +\\
  
 Ethanal has also been detected in cold clouds:\\ Ethanal has also been detected in cold clouds:\\
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 **[[https://doi.org/10.1086/163018|The Detection of Acetaldehyde in Cold Dust Clouds]]**\\ **[[https://doi.org/10.1086/163018|The Detection of Acetaldehyde in Cold Dust Clouds]]**\\
 //Astrophys. J.// **290**, 609–614 (1985).\\ //Astrophys. J.// **290**, 609–614 (1985).\\
-Both //A// and //E// internal rotation components of the 1<sub>01</sub> – 0<sub>00</sub> transition near 19264 MHz were detected with the NRAO 140-foot telescope toward TMC-1 and L134N.+Both //A// and //E// internal rotation components of the 1<sub>01</sub> – 0<sub>00</sub> transition near 19264 MHz were detected with the NRAO 140-foot telescope toward TMC-1 and L134N.\\ 
 +\\
  
 It was also found in one of three translucent clouds (CB 17):\\ It was also found in one of three translucent clouds (CB 17):\\
 B. E. Turner, R. Terzieva, and E. Herbst,\\ B. E. Turner, R. Terzieva, and E. Herbst,\\
 **[[https://doi.org/10.1086/307300|The Physics and Chemistry of Small Translucent Molecular Clouds. XII. More Complex Species Explainable by Gas-Phase Processes]]**\\ **[[https://doi.org/10.1086/307300|The Physics and Chemistry of Small Translucent Molecular Clouds. XII. More Complex Species Explainable by Gas-Phase Processes]]**\\
-//Astrophys. J.// **518**, 699–732 (1999).+//Astrophys. J.// **518**, 699–732 (1999).\\ 
 +\\
  
 A. Belloche, H. S. P. Müller, K. M. Menten, P. Schilke, and C. Comito\\ A. Belloche, H. S. P. Müller, K. M. Menten, P. Schilke, and C. Comito\\
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 **[[https://doi.org/10.1051/0004-6361/201321096|Complex Organic Molecules in the Interstellar Medium: IRAM 30 m Line Survey of Sagittarius B2(N) and (M)]]**\\ **[[https://doi.org/10.1051/0004-6361/201321096|Complex Organic Molecules in the Interstellar Medium: IRAM 30 m Line Survey of Sagittarius B2(N) and (M)]]**\\
 //Astron. Astrophys.// **559**, Art. No. A47 (2013).\\ //Astron. Astrophys.// **559**, Art. No. A47 (2013).\\
-They observed several transitions in the first excited torsional state. The vibrational temperature of about 150 K is higher than the rotational temperature of about 100 K. The difference was viewed as an indication of (far-) infrared pumping.+They observed several transitions in the first excited torsional state. The vibrational temperature of about 150 K is higher than the rotational temperature of about 100 K. The difference was viewed as an indication of (far-) infrared pumping.\\ 
 +\\
  
 J. K. Jørgensen, H. S. P. Müller, H. Calcutt, A. Coutens, M. N. Drozdovskaya, K. I. Öberg, M. V. Persson, V. Taquet, E. F. van Dishoeck, and S. F. Wampfler\\ J. K. Jørgensen, H. S. P. Müller, H. Calcutt, A. Coutens, M. N. Drozdovskaya, K. I. Öberg, M. V. Persson, V. Taquet, E. F. van Dishoeck, and S. F. Wampfler\\
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 **[[https://doi.org/10.1051/0004-6361/201731667|The ALMA-PILS Survey: Isotopic Composition of Oxygen-containing Complex Organic Molecules toward IRAS 16293–2422B]]**\\ **[[https://doi.org/10.1051/0004-6361/201731667|The ALMA-PILS Survey: Isotopic Composition of Oxygen-containing Complex Organic Molecules toward IRAS 16293–2422B]]**\\
 //Astron. Astrophys.// **620**, Art. No. A170 (2018).\\ //Astron. Astrophys.// **620**, Art. No. A170 (2018).\\
-The results were obtained in the course of a line survey of the solar-type protostellar binary IRAS 16293–2422 with ALMA covering the frequency range 329.1–362.9 GHz. The authors only investigated source B. They detected for the first time both <sup>13</sup>C isotopomers as well as the CH<sub>3</sub>CDO species. The D/H ratio per H atom is about 0.08. The <sup>12</sup>C/<sup>13</sup>C ratio is compatible with the local ISM ratio. Ethanal is among the molecules with colder rotational temperatures of around 125 K in that hot corino.+The results were obtained in the course of a line survey of the solar-type protostellar binary IRAS 16293–2422 with ALMA covering the frequency range 329.1–362.9 GHz. The authors only investigated source B. They detected for the first time both <sup>13</sup>C isotopomers as well as the CH<sub>3</sub>CDO species. The D/H ratio per H atom is about 0.08. The <sup>12</sup>C/<sup>13</sup>C ratio is compatible with the local ISM ratio. Ethanal is among the molecules with colder rotational temperatures of around 125 K in that hot corino.\\ 
 +\\
  
 L. H. Coudert, L. Margulès, C. Vastel, R. Motiyenko, E. Caux, and J.-C. Guillemin\\ L. H. Coudert, L. Margulès, C. Vastel, R. Motiyenko, E. Caux, and J.-C. Guillemin\\
 extended the CH<sub>2</sub>DCHO line list considerably. Subsequently, they were able to detect this isotopolog in the PILS data as well. They estimated the column density to be slightly higher than that of CH<sub>3</sub>CDO, as expected.\\ extended the CH<sub>2</sub>DCHO line list considerably. Subsequently, they were able to detect this isotopolog in the PILS data as well. They estimated the column density to be slightly higher than that of CH<sub>3</sub>CDO, as expected.\\
-**[[http://dx.doi.org/10.1051/0004-6361/201834827|Astrophysical detections and databases for the mono deuterated+**[[https://doi.org/10.1051/0004-6361/201834827|Astrophysical detections and databases for the mono deuterated 
 species of acetaldehyde CH<sub>2</sub>DCOH and CH<sub>3</sub>COD]]**\\ species of acetaldehyde CH<sub>2</sub>DCOH and CH<sub>3</sub>COD]]**\\
-//Astron. Astrophys.// **624**, Art. No. A70 (2019).+//Astron. Astrophys.// **624**, Art. No. A70 (2019).\\ 
 +The observations are based on PILS.\\ 
 +\\
  
-----+J. Ferrer Asensio, S. Spezzano, L. H. Coudert, V. Lattanzi, C. P. Endres, J. K. Jørgensen, and P. Caselli\\ 
 +described the\\ 
 +**[[https://doi.org/10.1051/0004-6361/202245442|Millimetre and Sub-millimetre Spectroscopy of Doubly Deuterated Acetaldehyde (CHD<sub>2</sub>CHO) and First Detection towards IRAS 16293−2422]]**\\ 
 +//Astron. Astrophys.// **670**, Art. No. A177 (2023).\\ 
 +The observations are based on PILS. The authors determine a CHD<sub>2</sub>CHO to CH<sub>2</sub>DCOH ratio of ~0.21. It is also worthwhile to compare the column densities with that of the main isotopic species. This translates to a deueration degree of ~0.017 per H atom for CH<sub>2</sub>DCOH and ~0.060 for CHD<sub>2</sub>CHO. Such enhancement in the degree of deueration in doubly or higher deuterated isotopologs compared with sinly deuterated variants has been found commonly.\\ 
 +\\
  
-Contributor(s): H. S. P. Müller; 11, 2009; 03, 2012; 01, 2014; 10, 2017; 01, 2019; 04, 2019+----
  
 +Contributor(s): H. S. P. Müller; 11, 2009; 03, 2012; 01, 2014; 10, 2017; 01, 2019; 04, 2019; 03, 2023.
  
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