On the energy-specific photodissociation pathways of 14N2 and 14N15N isotopomers to N atoms of different reactivity: a quantum dynamical perspective

Gelfand, Natalia; Komarova, Ksenia; Remacle, Françoise; Levine, R. D.

doi:10.26434/chemrxiv-2023-gcdwh

Cited by 3 publications

(8 citation statements)

References 24 publications

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“… 27 − 29 The states of given symmetry and multiplicity are mixed by strong nonadiabatic terms. 30 The considerable spatial and state selectivity of the spin–orbit coupling; see, for example refs ( 2 and 31 ), is displayed for N 2 in ref ( 32 ) and here in Scheme 1 .…”

mentioning

confidence: 85%

“… 3 , 24 , 27 , 36 − 38 We here consider three optically accessible bound singlet 1 Σ u + and six dissociative states: one 3 Σ u – , four 3 Π u and one 5 Π u electronic states ( Figure 1 A). This set of states was defined based on our recent computational simulation 32 of the experimentally measured branching fractions into N( 4 S 3/2 ) + N( 2 D J ) and N( 4 S 3/2 ) + N( 2 P J ) product channels shown with the blue and orange arrows in Figure 1 A, respectively. The triplet 3 Π u states have been known to be the primary channels for the photodissociation of the N 2 molecule.…”

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confidence: 99%

“… 27 , 36 , 37 A special case is at an excitation energy of 110,144 cm –1 where the dissociation of the triplet 3 Π u states is particularly slow and the contribution of the 1 3 Σ u – and 2 5 Π u electronic states is found to be dominant. 32 …”

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confidence: 99%

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Recombination of N Atoms in a Manifold of Electronic States Simulated by Time-Reversed Nonadiabatic Photodissociation Dynamics of N₂

Gelfand

Remacle

Levine

2023

J. Phys. Chem. Lett.

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Following a single photon VUV absorption, the N2 molecule dissociates into distinct channels leading to N atoms of different reactivities. The optically accessible singlets are bound, and dissociation occurs through spin–orbit induced transfer to the triplets. There is a forest of coupled electronic states, and we here aim to trace a path along the nonadiabatic couplings toward a particular exit channel. To achieve this, we apply a time-reversed quantum dynamical approach that corresponds to a dissociation running back. It begins with an atom–atom relative motion in a particular product channel. Starting with a Gaussian wave packet at the dissociation region of N2 and propagating it backward in time, one can see the population transferring among the triplets due to a strong nonadiabatic interaction between these states. Simultaneously, the optically active singlets get populated because of spin–orbit coupling to the triplets. Thus, backward propagation traces the nonradiative association of nitrogen atoms.

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confidence: 99%

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Recombination of N Atoms in a Manifold of Electronic States Simulated by Time-Reversed Nonadiabatic Photodissociation Dynamics of N₂

Gelfand

Remacle

Levine

2023

J. Phys. Chem. Lett.

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“…7(a), the population of the triplets 3 P u is very low and so even other low populated states become important. In a previous study, 73 we proposed that the reason of this low population is the notably long lifetime of the excited singlet state.…”

Section: Vuv Optically Excited and Dissociative States Of Nmentioning

confidence: 95%

“…[69][70][71][72] We recently computed a realistic energy dependence in the dissociation branching arising from excitation of different single vibrational levels of 1 S + u electronic states of N 2 . 65,73 These computations started from the molecule in the ground electronic state and excited it by a polarized laser pulse of a very long duration and of the required mean energy. In the present work we make a step further and present the results of the branching into the channels N( 4 S) + N( 2 D) (Channel 1) and N( 4 S) + N( 2 P) (Channel 2) accessed through the excited 1 P u states of N 2 .…”

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confidence: 99%

Nonadiabatic quantum dynamics explores non-monotonic photodissociation branching of N₂ into the N(⁴S) + N(²D) and N(⁴S) + N(²P) product channels

Gelfand,

Komarova,

Remacle

et al. 2024

Phys. Chem. Chem. Phys.

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High-Energy Quantum Dynamics of the ¹⁵N + o-¹⁴N¹⁴N Rovibrational Activation and Isotope Exchange Processes

Guillon,

Lepers,

Tak

et al. 2023

J. Phys. Chem. A

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We report full quantum reaction probabilities, computed within the framework of time-independent quantum mechanics using hyperspherical coordinates, for the 15 N + 14 N 14 N inelastic and reactive collision processes, restricted to total angular momentum J = 0, for kinetic energies up to 4.5 eV. We take advantage of the nonzero (i = 1) nuclear spin of 14 N, leading to the existence of two nuclear spin isomers of 14 N 14 N, namely, ortho-and para-14 N 14 N, to restrict the study to the ortho molecular nitrogen species, with even rotational quantum number j = 0, 2, ... states. Specifically, we start with diatomic reagents ortho-14 N 14 N in the initial rotational state j = 0. A comparison with similar works previously published by other groups using time-dependent wave packet and quasi-classical trajectory methods for the 14 N + 14 N 14 N fully symmetric collision is given. We find that reactive processes 15 N + 14 N 14 N involving atom exchange do not happen for collision energies less than 2.2 eV. Collisions at energies of around 2.0 eV are most effective for populating reactants' rovibrational states, that is, for inelastic scattering, whereas those at energies close to 5.0 eV yield a newly formed 14 N 15 N isotopologue in a wide variety of excited vibrational levels.

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On the energy-specific photodissociation pathways of 14N2 and 14N15N isotopomers to N atoms of different reactivity: a quantum dynamical perspective

Cited by 3 publications

References 24 publications

Recombination of N Atoms in a Manifold of Electronic States Simulated by Time-Reversed Nonadiabatic Photodissociation Dynamics of N₂

Recombination of N Atoms in a Manifold of Electronic States Simulated by Time-Reversed Nonadiabatic Photodissociation Dynamics of N₂

Nonadiabatic quantum dynamics explores non-monotonic photodissociation branching of N₂ into the N(⁴S) + N(²D) and N(⁴S) + N(²P) product channels

High-Energy Quantum Dynamics of the ¹⁵N + o-¹⁴N¹⁴N Rovibrational Activation and Isotope Exchange Processes

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On the energy-specific photodissociation pathways of 14N2 and 14N15N isotopomers to N atoms of different reactivity: a quantum dynamical perspective

Cited by 3 publications

References 24 publications

Recombination of N Atoms in a Manifold of Electronic States Simulated by Time-Reversed Nonadiabatic Photodissociation Dynamics of N2

Recombination of N Atoms in a Manifold of Electronic States Simulated by Time-Reversed Nonadiabatic Photodissociation Dynamics of N2

Nonadiabatic quantum dynamics explores non-monotonic photodissociation branching of N2 into the N(4S) + N(2D) and N(4S) + N(2P) product channels

High-Energy Quantum Dynamics of the 15N + o-14N14N Rovibrational Activation and Isotope Exchange Processes

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Recombination of N Atoms in a Manifold of Electronic States Simulated by Time-Reversed Nonadiabatic Photodissociation Dynamics of N₂

Recombination of N Atoms in a Manifold of Electronic States Simulated by Time-Reversed Nonadiabatic Photodissociation Dynamics of N₂

Nonadiabatic quantum dynamics explores non-monotonic photodissociation branching of N₂ into the N(⁴S) + N(²D) and N(⁴S) + N(²P) product channels

High-Energy Quantum Dynamics of the ¹⁵N + o-¹⁴N¹⁴N Rovibrational Activation and Isotope Exchange Processes