Upper limits to interstellar NH+and para-NH2−abundances

Persson, C. M.; Hajigholi, M.; Hassel, G. E.; Olofsson, A. O. H.; Black, J. H.; Herbst, Eric; Müller, H. S. P.; Cernicharo, J.; Wirström, E. S.; Olberg, M.; Hjalmarson, Å.; Lis, D. C.; Cuppen, H. M.; Gérin, M.; Menten, K. M.

doi:10.1051/0004-6361/201423748

Cited by 21 publications

(16 citation statements)

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“…This is in contrast to many other species, for example, CH (Gerin et al 2010), H 2 O (Flagey et al 2013) and HF (Sonnentrucker et al 2010), which trace lower density interstellar gas than NH 2 (see e.g. chemical models for the nitrogen hydrides in different physical conditions in Persson et al 2014). We did, however, find redshifted absorption in W51, at V LSR ∼ 68 km s −1 , tracing a dense clump in a filament interacting with W51, also detected in C 3 , HDO and NH 3 (Mookerjea et al 2014).…”

Section: Results and Modellingmentioning

confidence: 92%

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Ortho-to-para ratio of NH₂

Persson

Olofsson

Gal

et al. 2016

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We have used the Herschel-HIFI instrument to observe the two nuclear spin symmetries of amidogen (NH 2 ) towards the high-mass star-forming regions W31C (G10.6−0.4), W49N (G43.2−0.1), W51 (G49.5−0.4), and G34.3+0.1. The aim is to investigate the ratio of nuclear spin types, the ortho-to-para ratio (OPR) of NH 2 in the translucent interstellar gas, where it is traced by the line-of-sight absorption, and in the envelopes that surround the hot cores. The HIFI instrument allows spectrally resolved observations of NH 2 that show a complicated pattern of hyperfine structure components in all its rotational transitions. The excited NH 2 transitions were used to construct radiative transfer models of the hot cores and surrounding envelopes to investigate the excitation and possible emission of the ground-state rotational transitions of ortho-NH 2 N Ka,Kc J = 1 1,1 3/2-0 0,0 1/2 (953 GHz) and para-NH 2 2 1,2 5/2-1 0,1 3/2 (1444 GHz) used in the OPR calculations. Our best estimate of the average OPR in the envelopes lie above the high-temperature limit of three for W49N, specifically 3.5 with formal errors of ±0.1, but for W31C, W51, and G34.3+0.1 we find lower values of 2.5 ± 0.1, 2.7 ± 0.1, and 2.3 ± 0.1, respectively. Values this low are strictly forbidden in thermodynamical equilibrium since the OPR is expected to increase above three at low temperatures. In the translucent interstellar gas towards W31C, where the excitation effects are low, we find similar values between 2.2 ± 0.2 and 2.9 ± 0.2. In contrast, we find an OPR of 3.4 ± 0.1 in the dense and cold filament connected to W51 and also two lower limits of 4.2 and 5.0 in two other translucent gas components towards W31C and W49N. At low temperatures (T 50 K) the OPR of H 2 is <10 −1 , far lower than the terrestrial laboratory normal value of three. In this para-enriched H 2 gas, our astrochemical models can reproduce the variations of the observed OPR, both below and above the thermodynamical equilibrium value, by considering nuclear-spin gas-phase chemistry. The models suggest that values below three arise in regions with temperatures 20−25 K, depending on time, and values above three at lower temperatures.

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Section: Results and Modellingmentioning

confidence: 92%

“…Once formed, NH + 4 undergoes dissociative recombination with electrons resulting in the production of NH 3 and NH 2 (see Fig. 3 in Persson et al 2014). NH 2 can also form through the dissociative recombination of NH + 3 .…”

Section: Deviation From Thermodynamical Equilibriummentioning

confidence: 99%

Ortho-to-para ratio of NH₂

Persson

Olofsson

Gal

et al. 2016

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“…With our improved line positions we can test the tentative assignment of an observed transition towards the middle part of the giant molecular cloud Sagittarius B2 (SgrB2(M)) to the NH − 2 anion by Persson et al [21]. Their observation with the Heterodyne Instrument for the Far-Infrared (HIFI) on board the Herschel Space Observatory was attributed to a transition with a rest frequency of between 933973 and 934009 GHz.…”

Section: Thzmentioning

confidence: 89%

“…Recently, NH − 2 , a molecular anion with a similarly small electron binding energy as H − , has been tentatively assigned to a previously unidentified absorption feature near 934 GHz [21]. However, astrochemical model calculations by the same authors predict an expected abundance of NH − 2 far below the detection limit.…”

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Rotational Spectroscopy of a Triatomic Molecular Anion

et al. 2018

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Rotational transitions of the nonlinear triatomic molecular anion NH_{2}^{-} have been observed by terahertz spectroscopy in a cryogenic radio frequency ion trap. Absorption of terahertz photons has been probed by rotational state-dependent photodetachment of the trapped negative ions near the detachment threshold. Using this two-photon scheme, the two lowest rotational transitions for the asymmetric top rotor NH_{2}^{-} have been found. For the para nuclear spin configuration, the 1_{0}←0_{0} transition frequency was determined to be 933 954(2) MHz, and for the ortho configuration the 1_{+1}←1_{-1} transition frequency was determined to be 447 375(3) MHz. This result appears to preclude the recent tentative assignment of an interstellar absorption feature to NH_{2}^{-}.

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“…Photoionised nebulae with densities n e 0.1 cm −3 can be ruled out because the 205 μm line would appear strongly in emission. Models of neutral, partly molecular gas at low temperature, T K 100 K, are unable to explain the observed absorption because the N + abundance in neutral gas is too low at the adopted ionisation rate and the observed abundance would imply an amount of NH + in conflict with observed upper limits (Persson et al 2012(Persson et al , 2014. The total cooling provided by [N ii] in our models is dominated by the 6548 Å and 6583 Å transitions (86%), while the 205 μm and 122 μm fine-structure transitions account for 12%.…”

Section: Radex Modellingmentioning

confidence: 99%

First detection of [N II] 205μm absorption in interstellar gas

Persson

Gérin

Mookerjea

et al. 2014

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We present high resolution [N ii] 205 μm ( 3 P 1 − 3 P 0 ) spectra obtained with Herschel-HIFI towards a small sample of far-infrared bright star forming regions in the Galactic plane: W 31C (G10.6−0.4), W 49N (G43.2−0.1), W 51 (G49.5−0.4), and G34.3+0.1. The detection of the 205 μm line in absorption emphasises the importance of a high spectral resolution, and also offers a new tool for investigation of the WIM.

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Upper limits to interstellar NH⁺and para-NH₂⁻abundances

Cited by 21 publications

References 50 publications

Ortho-to-para ratio of NH₂

Ortho-to-para ratio of NH₂

Rotational Spectroscopy of a Triatomic Molecular Anion

First detection of [N II] 205μm absorption in interstellar gas

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Upper limits to interstellar NH+and para-NH2−abundances

Cited by 21 publications

References 50 publications

Ortho-to-para ratio of NH2

Ortho-to-para ratio of NH2

Rotational Spectroscopy of a Triatomic Molecular Anion

First detection of [N II] 205μm absorption in interstellar gas

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Product

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Upper limits to interstellar NH⁺and para-NH₂⁻abundances

Ortho-to-para ratio of NH₂

Ortho-to-para ratio of NH₂