Your search keyword '"Martin-Drumel, M. -A."' showing total 52 results

51. First detection of NHD and ND2 in the interstellar medium

Author

Paola Caselli, Olivier Pirali, Filippo Tamassia, Barbara M. Giuliano, Marie-Aline Martin-Drumel, Mattia Melosso, Luca Bizzocchi, Olli Sipilä, Luca Dore, Elena Redaelli, Melosso M., Bizzocchi L., Sipila O., Giuliano B.M., Dore L., Tamassia F., Martin-Drumel M.-A., Pirali O., Redaelli E., and Caselli P.

Subjects

Physics, Astrochemistry, Amidogen, Line: identification, Continuum (design consultancy), Astronomy and Astrophysics, Context (language use), ISM: molecule, Astrophysics, 010402 general chemistry, 01 natural sciences, ISM: abundance, 0104 chemical sciences, Interstellar medium, chemistry.chemical_compound, Deuterium, chemistry, Space and Planetary Science, 0103 physical sciences, Protostar, Isotopologue, Submillimeter: ISM, 010303 astronomy & astrophysics

Abstract

Context. Deuterium fractionation processes in the interstellar medium (ISM) have been shown to be highly efficient in the family of nitrogen hydrides. To date, observations have been limited to ammonia (NH2D, NHD2, ND3) and imidogen radical (ND) isotopologues. Aims. We want to explore the high-frequency windows offered by the Herschel Space Observatory to search for deuterated forms of the amidogen radical NH2 and to compare the observations against the predictions of our comprehensive gas-grain chemical model. Methods. Making use of the new molecular spectroscopy data recently obtained at high frequencies for NHD and ND2, we searched for both isotopologues in the spectral survey toward the Class 0 protostar IRAS 16293-2422, a source in which NH3, NH, and their deuterated variants have previously been detected. We used the observations carried out with HIFI (Heterodyne Instrument for the Far-Infrared) in the framework of the key program “Chemical Herschel surveys of star forming regions” (CHESS). Results. We report the first detection of interstellar NHD and ND2. Both species are observed in absorption against the continuum of the protostar. From the analysis of their hyperfine structure, accurate excitation temperature and column density values are determined. The latter were combined with the column density of the parent species NH2 to derive the deuterium fractionation in amidogen. We find a high deuteration level of amidogen radical in IRAS 16293-2422, with a deuterium enhancement about one order of magnitude higher than that predicted by earlier astrochemical models. Such a high enhancement can only be reproduced by a gas-grain chemical model if the pre-stellar phase preceding the formation of the protostellar system has a long duration: on the order of one million years. Conclusions. The amidogen D/H ratio measured in the low-mass protostar IRAS 16293-2422 is comparable to that derived for the related species imidogen and much higher than that observed for ammonia. Additional observations of these species will provide more insights into the mechanism of ammonia formation and deuteration in the ISM. Finally, we indicate the current possibilities to further explore these species at submillimeter wavelengths.

Published

2020

52. Tunneling motion and splitting in the CH 2 OH radical: (Sub-)millimeter wave spectrum analysis.

Author

Coudert LH, Chitarra O, Spaniol JT, Loison JC, Martin-Drumel MA, and Pirali O

Abstract

The (sub-)millimeter wave spectrum of the non-rigid CH 2 OH radical is investigated both experimentally and theoretically. Ab initio calculations are carried out to quantitatively characterize its potential energy surface as a function of the two large amplitude ∠H 1 COH and ∠H 2 COH dihedral angles. It is shown that the radical displays a large amplitude torsional-like motion of its CH 2 group with respect to the OH group. The rotation-torsion levels computed with the help of a 4D Hamiltonian accounting for this torsional-like motion and for the overall rotation exhibit a tunneling splitting, in agreement with recent experimental investigations, and a strong rotational dependence of this tunneling splitting on the rotational quantum number K a due to the rotation-torsion Coriolis coupling. Based on an internal axis method approach, a fitting Hamiltonian accounting for tunneling effects and for the fine and hyperfine structure is built and applied to the fitting of the new (sub)-millimeter wave transitions measured in this work along with previously available high-resolution data. 778 frequencies and wavenumbers are reproduced with a unitless standard deviation of 0.79 using 27 parameters. The N = 0 tunneling splitting, which could not be determined unambiguously in the previous high-resolution investigations, is determined based on its rotational dependence.

Published

2022