The dissociative recombination rate coefficients of H+3, HN+2, and HCO+

Amano, T.

doi:10.1063/1.458594

Cited by 148 publications

(93 citation statements)

References 32 publications

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“…The new model takes into account the new branching ratios of the N 2 H + dissociative recombination (Molek et al 2007), and computes the pre-exponential factors of the reverse reactions involved in the deuterium fractionation of CH + 3 with the proper factors involved in the translational partition functions. In addition, we have included the branching ratios of the electronic recombination of HCO + from Amano (1990), where the channel towards CO is found to be predominant. The radiative association reactions of CH + 3 and deuterated substitutes with H 2 have been derived from the theoretical predictions of Bacchus-Montabonel et al (2000), who provide values for different temperatures.…”

Section: Comparison To Gas-phase Modelmentioning

confidence: 99%

Deuterium chemistry in the Orion Bar PDR

Parise¹,

Leurini

Schilke³

et al. 2009

A&A

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Context. High levels of deuterium fractionation in gas-phase molecules are usually associated with cold regions, such as prestellar cores. Significant fractionation ratios are also observed in hot environments such as hot cores or hot corinos, where they are believed to be produced by the evaporation of the icy mantles surrounding dust grains, and are thus remnants of a previous cold (either gasphase or grain surface) chemistry. The recent detection of DCN towards the Orion Bar, in a clump at a characteristic temperature of 70 K, has shown that high deuterium fractionation can also be detected in PDRs. The Orion Bar clumps thus appear to be a good environment for the observational study of deuterium fractionation in luke warm gas, allowing us to validate chemistry models for a different temperature range, where dominating fractionation processes are predicted to differ from those in cold gas (<20 K). Aims. We aimed to study observationally in detail the chemistry at work in the Orion Bar PDR, to understand whether DCN is either produced by ice mantle evaporation or is the result of warm gas-phase chemistry, involving the CH 2 D + precursor ion (which survives higher temperatures than the usual H 2 D + precursor). Methods. Using the APEX and the IRAM 30 m telescopes, we targeted selected deuterated species towards two clumps in the Orion Bar. Results. We confirmed the detection of DCN and detected two new deuterated molecules (DCO + and HDCO) towards one clump in the Orion Bar PDR. Significant deuterium fractionations are found for HCN and H 2 CO, but we measured a low fractionation in HCO + . We also provide upper limits to other molecules relevant to deuterium chemistry. Conclusions. We argue that grain evaporation in the clumps is unlikely to be a dominant process, and we find that the observed deuterium fractionation ratios are consistent with predictions of pure gas-phase chemistry models at warm temperatures (T ∼ 50 K). We show evidence that warm deuterium chemistry driven by CH 2 D + is at work in the clumps.

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Section: Comparison To Gas-phase Modelmentioning

confidence: 99%

Deuterium chemistry in the Orion Bar PDR

Parise¹,

Leurini

Schilke³

et al. 2009

A&A

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“…If one is unaware of this, one may conclude that one observes binary, rather than ternary recombination. Bates et al [12] pointed this out in their famous 'enigma' paper while trying to explain the experimental observations in H + 3 afterglows of Amano [5]. The collisional part of CRR (the first term in equation (2.1)), when written as A + + 2e − → A(n, l) + e − , looks like the inverse of electron-impact ionization, but the highly excited product neutrals (with principal and angular momentum quantum numbers n and l) are quickly re-ionized and enter an approximate Saha equilibrium with the free electrons.…”

Section: (A) Collisional Radiative Recombination and Collisional Dissmentioning

confidence: 99%

“…Afterglow plasmas at higher densities, however, explore additional mechanisms to return to the neutral state, as is immediately apparent when one examines historical recombination data. Figure 1 compares selected afterglow rate coefficients [2,3,5,6] to the thermal recombination coefficient inferred from earlier ISR experiments [4].…”

Section: Introductionmentioning

confidence: 99%

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Kinetic processes in recombining H ₃ ⁺ plasmas

Johnsen

2012

Phil. Trans. R. Soc. A.

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“…However, the available literature on the DR of this molecular ion is scarce and, from the theoretical point of view, somehow incomplete. Several experiments on DR in N 2 H + have been made [21][22][23] producing somewhat different rate coefficients as shown on the right panel of Fig. 4.…”

Section: Introductionmentioning

confidence: 99%

Simplified model to describe the dissociative recombination of linear polyatomic ions of astrophysical interest

Douguet

Santos

Kokoouline

et al. 2015

EPJ Web of Conferences

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Abstract. We present results of a theoretical study on dissociative recombination of the HCNH + , HCO + and N 2 H + linear polyatomic ions at low energies using a simple theoretical model. In the present study, the indirect mechanism for recombination proceeds through the capture of the incoming electron in excited vibrational Rydberg states attached to the degenerate transverse modes of the linear ions. The strength of the non-adiabatic coupling responsible for dissociative recombination is determined directly from the near-threshold scattering matrix obtained numerically using the complex Kohn variational method. The final cross sections for the process are compared with available experimental data. It is demonstrated that at low collision energies, the major contribution to the dissociative recombination cross section is due to the indirect mechanism.

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The dissociative recombination rate coefficients of H+3, HN+2, and HCO+

Cited by 148 publications

References 32 publications

Deuterium chemistry in the Orion Bar PDR

Deuterium chemistry in the Orion Bar PDR

Kinetic processes in recombining H ₃ ⁺ plasmas

Simplified model to describe the dissociative recombination of linear polyatomic ions of astrophysical interest

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The dissociative recombination rate coefficients of H+3, HN+2, and HCO+

Cited by 148 publications

References 32 publications

Deuterium chemistry in the Orion Bar PDR

Deuterium chemistry in the Orion Bar PDR

Kinetic processes in recombining H 3 + plasmas

Simplified model to describe the dissociative recombination of linear polyatomic ions of astrophysical interest

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Kinetic processes in recombining H ₃ ⁺ plasmas