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molecules:ism:meo [2019/02/25 22:38] – external edit 127.0.0.1 | molecules:ism:meo [2019/10/23 17:19] (current) – mueller |
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===== Detection of the Methoxy Radical, CH3O, 2Ei, in the ISM ===== | ===== Detection of the Methoxy Radical, CH3O, in the ISM ===== |
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The methoxy radical, CH<sub>3</sub>O, is a symmetric top rotor with a doubly degenerate ground electronic state and large spin-orbit splitting. The Ω = 3/2 spin component (//J// = //N// + 1/2) is lower in energy than the 1/2 component. Λ-doubling can usually be resolved for //K// = 0, 1, and to some extent also for //K// = –1. Moreover, the molecule exhibts complex fine and hypperfine splitting. Seven stronger hyperfine components of the //N// = 1 – 0 (//F// = 2 – 1; Λ = –1 and +1 near 82.6 GHz) and //N// = 2 – 1 (both Λ components for each //F// = 4 – 3 and 3 – 2, and the –1 component for 2 – 1 near 137.5 GHz) were detected in emission with reasonable to good signal-to-noise ratio in the course of a 3 and 2 mm molecular line survey with the IRAM 30 m radiotelescope toward B1-b. Barnard 1 is a dark clould which is subjected to radiation or shocks.\\ | The methoxy radical, CH<sub>3</sub>O, is a symmetric top rotor with a doubly degenerate ground electronic state and large spin-orbit splitting. The Ω = 3/2 spin component (//J// = //N// + 1/2) is lower in energy than the 1/2 component. Λ-doubling can usually be resolved for //K// = 0, 1, and to some extent also for //K// = –1. Moreover, the molecule exhibts complex fine and hypperfine splitting. Seven stronger hyperfine components of the //N// = 1 – 0 (//F// = 2 – 1; Λ = –1 and +1 near 82.6 GHz) and //N// = 2 – 1 (both Λ components for each //F// = 4 – 3 and 3 – 2, and the –1 component for 2 – 1 near 137.5 GHz) were detected in emission with reasonable to good signal-to-noise ratio in the course of a 3 and 2 mm molecular line survey with the IRAM 30 m radiotelescope toward B1-b. Barnard 1 is a dark clould which is subjected to radiation or shocks.\\ |
J. Cernicharo, N. Marcelino, E. Roueff, M. Gerin, A. Jiménez-Escobar, and G. M. Muñoz Caro,\\ | J. Cernicharo, N. Marcelino, E. Roueff, M. Gerin, A. Jiménez-Escobar, and G. M. Muñoz Caro,\\ |
**[[http://dx.doi.org/10.1088/2041-8205/759/2/L43|Discovery of the Methoxy Radical, CH<sub>3</sub>O, toward B1: Dust Grain and Gas-phase Chemistry in Cold Dark Clouds]]**\\ | **[[https://doi.org/10.1088/2041-8205/759/2/L43|Discovery of the Methoxy Radical, CH<sub>3</sub>O, toward B1: Dust Grain and Gas-phase Chemistry in Cold Dark Clouds]]**\\ |
//Astrophys. J.// **759**, Art. No. L43 (2012). | //Astrophys. J.// **759**, Art. No. L43 (2012). |
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A. Bacmann and A. Faure\\ | A. Bacmann and A. Faure\\ |
investigated\\ | investigated\\ |
**[[http://dx.doi.org/10.1051/0004-6361/201526198|The origin of gas-phase HCO and CH<sub>3</sub>O radicals in prestellar cores]]**\\ | **[[https://doi.org/10.1051/0004-6361/201526198|The origin of gas-phase HCO and CH<sub>3</sub>O radicals in prestellar cores]]**\\ |
//Astron Astrophys.// **587**, Art. No. A130 (2016).\\ | //Astron Astrophys.// **587**, Art. No. A130 (2016).\\ |
Transitions of the //N// = 1 – 0, Σ = +1 groups of lines were detected with the IRAM 30 m telecope in four of eight sources, L1495A-S, L1689B, L1709A, and TMC-2. | Transitions of the //N// = 1 – 0, Σ = +1 groups of lines were detected with the IRAM 30 m telecope in four of eight sources, L1495A-S, L1689B, L1709A, and TMC-2. |
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Contributor(s): H. S. P. Müller 10, 2012; 02, 2016 | Contributor(s): H. S. P. Müller 10, 2012; 02, 2016 |
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