J. Ajay scite author profile

Isotopic fractionation in the photodissociation of N could explain the considerable variation in the N/N ratio in different regions of our galaxy. We previously proposed that such an isotope effect is due to coupling of photoexcited bound valence and Rydberg electronic states in the frequency range where there is strong state mixing. We here identify features of the role of the mass in the dynamics through a time-dependent quantum-mechanical simulation. The photoexcitation of N is by an ultrashort pulse so that the process has a sharply defined origin in time and so that we can monitor the isolated molecule dynamics in time. An ultrafast pulse is necessarily broad in frequency and spans several excited electronic states. Each excited molecule is therefore not in a given electronic state but in a superposition state. A short time after excitation, there is a fairly sharp onset of a mass-dependent large population transfer when wave packets on two different electronic states in the same molecule overlap. This coherent overlap of the wave packets on different electronic states in the region of strong coupling allows an effective transfer of population that is very mass dependent. The extent of the transfer depends on the product of the populations on the two different electronic states and on their relative phase. It is as if two molecules collide but the process occurs within one molecule, a molecule that is simultaneously in both states. An analytical toy model recovers the (strong) mass and energy dependence.

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Probing in Space and Time the Nuclear Motion Driven by Nonequilibrium Electronic Dynamics in Ultrafast Pumped N₂

Ajay

Šmydke

Remacle

et al. 2016

J. Phys. Chem. A

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An ultrafast electronic excitation of N2 in the vacuum ultraviolet creates a nonstationary coherent linear superposition of interacting valence and Rydberg states resulting in a net oscillating dipole moment. There is therefore a linear response to an electrical field that can be queried by varying the time delay between the pump and a second optical probe pulse. Both the pump and probe pulses are included in our computation as part of the Hamiltonian, and the time-dependent wave function for both electronic and nuclear dynamics is computed using a grid representation for the internuclear coordinate. Even on an ultrafast time scale there are several processes that can be discerned beyond the expected coherence oscillations. In particular, the coupling between the excited valence and Rydberg states of the same symmetry is very evident and can be directly probed by varying the delay between pulse and probe. For quite a number of vibrations the nuclear motion does not dephase the electronic disequilibrium. However, the nuclear motion does modulate the dipolar response by taking the wave packet in and out of the Franck-Condon region and by its strong influence on the coupling of the Rydberg and valence states. A distinct isotope effect arises from the dependence of the interstate coupling on the nuclear mass.

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Attophotochemistry: Coherent Electronic Dynamics and Nuclear Motion

Ajay

Komarova

Wildenberg

et al. 2018

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We describe and discuss the theoretical methodology we use to analyze and predict novel chemical phenomena made possible by attosecond electronic excitation. We describe the dynamics by solving the time dependent Schrödinger equation with the laser pulse treated exactly as part of the Hamiltonian. We include the explicit onset of the nuclear motion following such an ultrafast excitation. The coupling to the nuclei is discussed when using either an adiabatic or a diabatic basis for the electronic dynamics. We begin by analyzing the chemical physics that can be realized by such an ultrafast excitation. Driving chemical reactions specifically towards new channels by selective attosecond excitation is explored as well as the physical parameters that can be used in such a control. Elucidating the role of other variables such as the mass is also discussed. The results are illustrated by recent applications primarily to the N2, LiH and HCN systems.

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Electronic and Nuclear Dynamics for a Non-Equilibrium Electronic State: The Ultrafast Pumping of N2

Šmydke

Ajay

Remacle

et al. 2017

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J. Ajay

Time-dependent view of an isotope effect in electron-nuclear nonequilibrium dynamics with applications to N ₂

Probing in Space and Time the Nuclear Motion Driven by Nonequilibrium Electronic Dynamics in Ultrafast Pumped N₂

Attophotochemistry: Coherent Electronic Dynamics and Nuclear Motion

Electronic and Nuclear Dynamics for a Non-Equilibrium Electronic State: The Ultrafast Pumping of N2

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J. Ajay

Time-dependent view of an isotope effect in electron-nuclear nonequilibrium dynamics with applications to N 2

Probing in Space and Time the Nuclear Motion Driven by Nonequilibrium Electronic Dynamics in Ultrafast Pumped N2

Attophotochemistry: Coherent Electronic Dynamics and Nuclear Motion

Electronic and Nuclear Dynamics for a Non-Equilibrium Electronic State: The Ultrafast Pumping of N2

Contact Info

Product

Resources

About

Time-dependent view of an isotope effect in electron-nuclear nonequilibrium dynamics with applications to N ₂

Probing in Space and Time the Nuclear Motion Driven by Nonequilibrium Electronic Dynamics in Ultrafast Pumped N₂