Effect of rotational excitation of H<sub>2</sub> on isotopic exchange reaction with OD<sup>−</sup> at low temperatures

Roučka, Štěpán; Rednyk, Serhiy; Kovalenko, Artem; Tran, Thuy Dung; Plašil, R.; Kálosi, Ábel; Dohnal, Petr; Gerlich, D.; Glosı́k, J.

doi:10.1051/0004-6361/201833264

Cited by 9 publications

(10 citation statements)

References 41 publications

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“…In recent experiments with our apparatus (Zymak et al 2013;Plašil et al 2012;Roučka et al 2018) and in other 22-pole ion trap experiments (Hauser et al 2015;Endres et al 2017) it has been confirmed that the collisional temperature (here denoted simply T ) is slightly higher than the temperature of the copper box surrounding the ion trap (nominal ion trap temperature, T 22PT ). At the present experimental conditions, we can safely assume that the collisional temperature in the interaction of ions with H 2 does not exceed the ion trap temperature by more than 10 K. For simplicity of presentation, we define the collisional temperature as T = T 22PT + 5 K with an uncertainty of ±5 K.…”

Section: Experiments and Data Analysissupporting

confidence: 70%

Reaction of NH⁺, NH₂⁺, and NH₃⁺ ions with H₂ at low temperatures

Rednyk

Roučka

Kovalenko

et al. 2019

A&A

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Aims. We present an experimental investigation of the exothermic reactions of NH+, NH2+, and NH3+ ions with H2 at temperatures relevant for interstellar clouds. Methods. The reactions were studied using a variable-temperature 22-pole radio frequency ion trap instrument. Results. The temperature dependences of rate coefficients of these reactions have been obtained at temperatures from 15 up to 300 K. The reaction of NH+ with H2 has two channels, which lead to NH2+ ( ∼ 97%) and H+3 ( ∼ 3%) with nearly constant reaction rate coefficients (kaNH+(17 K) = 1.0 × 10−9 cm3 s−1 and kbNH+(17 K) = 4.0 × 10−11 cm3 s−1, respectively). The reaction of NH2+ with H2 produces only NH3+ ions. The measured rate coefficient monotonically decreases with increasing temperature from kNH2+(17 K) = 6 × 10−10 cm3 s−1 to kNH2+(300 K) = 2 × 10−10 cm3 s−1. The measured rate coefficient of the reaction of NH3+ with H2, producing NH+4, increases with decreasing temperature from 80 K down to 15 K, confirming that the reaction proceeds by tunnelling through a potential barrier.

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Section: Experiments and Data Analysissupporting

confidence: 70%

Reaction of NH⁺, NH₂⁺, and NH₃⁺ ions with H₂ at low temperatures

Rednyk

Roučka

Kovalenko

et al. 2019

A&A

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“…For a particular experimental arrangement (construction of the ion trap), RF amplitude, and He pressure, the kinetic temperature of trapped ions can be obtained by measuring the Doppler broadening of absorption lines of trapped ions (Glosik et al 2006;Jusko et al 2014). Several recent experiments with linear 22-pole RF ion traps (Zymak et al 2013;Endres et al 2017;Roucka et al 2018) confirmed that the collisional temperature (T) can be slightly higher than T 22PT . On the basis of these studies, we can safely assume that under the present experimental conditions, the collisional temperature in the interaction of N + ions with HD and D 2 does not exceed T 22PT by more than 10 K. For the presentation of our data, we define the collisional temperature as T = T 22PT + 5 K with an uncertainty of ±5 K. In the context of the interaction of N + ions with HD and D 2 , we will simply use the term temperature interchangeably with collisional temperature.…”

Section: Methodsmentioning

confidence: 98%

Reaction of N⁺ Ion with H₂, HD, and D₂ at Low Temperatures: Experimental Study of the Pathway to Deuterated Nitrogen-containing Molecules in the Interstellar Medium

Plašil

Roučka

Kovalenko

et al. 2022

ApJ

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This work is motivated by many observations of nitrogen hydrides including their isotopologues in the interstellar space. We studied the formation of NH+ and ND+ ions in the nearly thermoneutral hydrogen abstraction reactions of N+ ions with H2, HD, and D2 at temperatures from 300 K down to 15 K using a variable-temperature 22-pole radio frequency ion trap. For the reaction of N+ with HD, the branching ratios for production of ND+ and NH+ ions were also determined. The activation energies of all four reaction channels were determined from the temperature dependencies of the measured reaction rate coefficients. Under the assumption of no energy barriers on the reaction paths, we derive the vibrationless energy change (i.e., the difference of equilibrium Born–Oppenheimer potential energies of products and reactants) in the reactions as ΔE e = (103 ± 3) meV.

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“…Some of these reactions were studied in our laboratory at temperatures below 300 K using a temperature-variable radio-frequency ion trap. Recently we studied the isotope exchange reactions OH − + D 2 and OD − + H 2 (Mulin et al 2015;Roučka et al 2018). Note that reaction (1) is the reverse of reaction (3).…”

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confidence: 99%

Isotope Exchange Reaction of OH⁻ Anion with HD at Temperatures from 15 K up to 300 K: Ion Trap Study

Plašil,

Uvarova,

Rednyk

et al. 2023

ApJ

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This paper presents the results of an experimental study of the reaction of OH− anions with HD molecules leading to the formation of OD− anions. The study’s main goal was to obtain the temperature dependence of the reaction rate coefficient and determine the reaction’s enthalpy. This study was carried out at astrophysically relevant temperatures from 15 to 300 K. The reaction was studied using a temperature-variable cryogenic linear 22-pole radio-frequency ion trap. The rotational temperature of the OH− anions in the ion trap was characterized by near-threshold photodetachment spectroscopy. At 15 K, the measured reaction rate coefficient is 5 × 10−10 cm3 s−1. With increasing temperature, the reaction rate coefficient decreases monotonically to 5 × 10−11 cm3 s−1 at 300 K. Comparing with the previously determined rate coefficient of the reverse reaction of OD− anions with H2, we obtained the temperature dependence of the equilibrium constant. The enthalpy and entropy of the title reaction were determined in the studied temperature range as ΔH = (−23.9 ± 0.7 ± 2.6sys) meV and ΔS = (−8.5 ± 1.2 ± 1.4sys) J mol−1 K−1, respectively.

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Effect of rotational excitation of H₂ on isotopic exchange reaction with OD⁻ at low temperatures

Cited by 9 publications

References 41 publications

Reaction of NH⁺, NH₂⁺, and NH₃⁺ ions with H₂ at low temperatures

Reaction of NH⁺, NH₂⁺, and NH₃⁺ ions with H₂ at low temperatures

Reaction of N⁺ Ion with H₂, HD, and D₂ at Low Temperatures: Experimental Study of the Pathway to Deuterated Nitrogen-containing Molecules in the Interstellar Medium

Isotope Exchange Reaction of OH⁻ Anion with HD at Temperatures from 15 K up to 300 K: Ion Trap Study

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Effect of rotational excitation of H2 on isotopic exchange reaction with OD− at low temperatures

Cited by 9 publications

References 41 publications

Reaction of NH+, NH2+, and NH3+ ions with H2 at low temperatures

Reaction of NH+, NH2+, and NH3+ ions with H2 at low temperatures

Reaction of N+ Ion with H2, HD, and D2 at Low Temperatures: Experimental Study of the Pathway to Deuterated Nitrogen-containing Molecules in the Interstellar Medium

Isotope Exchange Reaction of OH− Anion with HD at Temperatures from 15 K up to 300 K: Ion Trap Study

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Effect of rotational excitation of H₂ on isotopic exchange reaction with OD⁻ at low temperatures

Reaction of NH⁺, NH₂⁺, and NH₃⁺ ions with H₂ at low temperatures

Reaction of NH⁺, NH₂⁺, and NH₃⁺ ions with H₂ at low temperatures

Reaction of N⁺ Ion with H₂, HD, and D₂ at Low Temperatures: Experimental Study of the Pathway to Deuterated Nitrogen-containing Molecules in the Interstellar Medium

Isotope Exchange Reaction of OH⁻ Anion with HD at Temperatures from 15 K up to 300 K: Ion Trap Study