Strong inverse kinetic isotope effect observed in ammonia charge exchange reactions

L. S. Petralia; A. Tsikritea; J. Loreau; T. P. Softley; B. R. Heazlewood

doi:10.1038/s41467-019-13976-8

Strong inverse kinetic isotope effect observed in ammonia charge exchange reactions

L. S. Petralia, A. Tsikritea, J. Loreau, T. P. Softley, B. R. Heazlewood^*

^*Corresponding author for this work

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12 Citations (Scopus)

Abstract

Isotopic substitution has long been used to understand the detailed mechanisms of chemical reactions; normally the substitution of hydrogen by deuterium leads to a slower reaction. Here, we report our findings on the charge transfer collisions of cold Xe ⁺ ions and two isotopologues of ammonia, NH ₃ and ND ₃. Deuterated ammonia is found to react more than three times faster than hydrogenated ammonia. Classical capture models are unable to account for this pronounced inverse kinetic isotope effect. Moreover, detailed ab initio calculations cannot identify any (energetically accessible) crossing points between the reactant and product potential energy surfaces, indicating that electron transfer is likely to be slow. The higher reactivity of ND ₃ is attributed to the greater density of states (and therefore lifetime) of the deuterated reaction complex compared to the hydrogenated system. Our observations could provide valuable insight into possible mechanisms contributing to deuterium fractionation in the interstellar medium.

Original language	English
Article number	173
Journal	Nature Communications
Volume	11
Issue number	1
DOIs	https://doi.org/10.1038/s41467-019-13976-8
Publication status	Published - 1 Dec 2020

Bibliographical note

Funding Information:
B.R.H. and T.P.S. acknowledge the financial support of the EPSRC (projects EP/ N004647/1 and EP/N032950/1). A.T. thanks the Clarendon Fund and Somerville College for providing her with a scholarship. J.L. thanks J. Liévin, M. Kas and N. Vaeck for useful discussions on the potential energy surface calculations.

Publisher Copyright:
© 2020, The Author(s).

ASJC Scopus subject areas

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/s41467-019-13976-8

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title = "Strong inverse kinetic isotope effect observed in ammonia charge exchange reactions",

abstract = "Isotopic substitution has long been used to understand the detailed mechanisms of chemical reactions; normally the substitution of hydrogen by deuterium leads to a slower reaction. Here, we report our findings on the charge transfer collisions of cold Xe + ions and two isotopologues of ammonia, NH 3 and ND 3. Deuterated ammonia is found to react more than three times faster than hydrogenated ammonia. Classical capture models are unable to account for this pronounced inverse kinetic isotope effect. Moreover, detailed ab initio calculations cannot identify any (energetically accessible) crossing points between the reactant and product potential energy surfaces, indicating that electron transfer is likely to be slow. The higher reactivity of ND 3 is attributed to the greater density of states (and therefore lifetime) of the deuterated reaction complex compared to the hydrogenated system. Our observations could provide valuable insight into possible mechanisms contributing to deuterium fractionation in the interstellar medium.",

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AU - Heazlewood, B. R.

N1 - Funding Information: B.R.H. and T.P.S. acknowledge the financial support of the EPSRC (projects EP/ N004647/1 and EP/N032950/1). A.T. thanks the Clarendon Fund and Somerville College for providing her with a scholarship. J.L. thanks J. Liévin, M. Kas and N. Vaeck for useful discussions on the potential energy surface calculations. Publisher Copyright: © 2020, The Author(s).

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N2 - Isotopic substitution has long been used to understand the detailed mechanisms of chemical reactions; normally the substitution of hydrogen by deuterium leads to a slower reaction. Here, we report our findings on the charge transfer collisions of cold Xe + ions and two isotopologues of ammonia, NH 3 and ND 3. Deuterated ammonia is found to react more than three times faster than hydrogenated ammonia. Classical capture models are unable to account for this pronounced inverse kinetic isotope effect. Moreover, detailed ab initio calculations cannot identify any (energetically accessible) crossing points between the reactant and product potential energy surfaces, indicating that electron transfer is likely to be slow. The higher reactivity of ND 3 is attributed to the greater density of states (and therefore lifetime) of the deuterated reaction complex compared to the hydrogenated system. Our observations could provide valuable insight into possible mechanisms contributing to deuterium fractionation in the interstellar medium.

AB - Isotopic substitution has long been used to understand the detailed mechanisms of chemical reactions; normally the substitution of hydrogen by deuterium leads to a slower reaction. Here, we report our findings on the charge transfer collisions of cold Xe + ions and two isotopologues of ammonia, NH 3 and ND 3. Deuterated ammonia is found to react more than three times faster than hydrogenated ammonia. Classical capture models are unable to account for this pronounced inverse kinetic isotope effect. Moreover, detailed ab initio calculations cannot identify any (energetically accessible) crossing points between the reactant and product potential energy surfaces, indicating that electron transfer is likely to be slow. The higher reactivity of ND 3 is attributed to the greater density of states (and therefore lifetime) of the deuterated reaction complex compared to the hydrogenated system. Our observations could provide valuable insight into possible mechanisms contributing to deuterium fractionation in the interstellar medium.

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Strong inverse kinetic isotope effect observed in ammonia charge exchange reactions

Abstract

Bibliographical note

ASJC Scopus subject areas

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