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Simulating Attochemistry: Which Dynamics Method to Use?

Thierry Tran1, Anthony Ferté1, Morgane Vacher1

  • 1Nantes Université, CNRS, CEISAM UMR 6230, F-44000 Nantes, France.

The Journal of Physical Chemistry Letters
|March 26, 2024
PubMed
Summary
This summary is machine-generated.

Attochemistry uses attosecond pulses to control molecular reactions. Current simulation methods like Tully surface hopping and Ehrenfest fail to capture nuclear motion driven by electronic coherence, crucial for attochemistry.

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Area of Science:

  • Quantum dynamics
  • Attochemistry
  • Computational chemistry

Background:

  • Attochemistry seeks to control molecular reactions using coherent electronic wavepackets generated by attosecond pulses.
  • Nonadiabatic dynamics methods are used to simulate these molecular processes, but their approximations are often unevaluated.
  • Assessing the accuracy of these simulation methods is crucial for advancing attochemistry.

Purpose of the Study:

  • To evaluate the performance of common mixed quantum-classical methods against a high-accuracy quantum dynamics method.
  • To assess the impact of approximations in simulating attochemical processes.
  • To understand the limitations of current simulation techniques in capturing key quantum phenomena.

Main Methods:

  • Comparison of Tully surface hopping and classical Ehrenfest methods with the DD-vMCG quantum dynamics method.
  • Simulation of valence ionization of fluorobenzene.
  • Analysis of nuclear motion in the branching space of a conical intersection.

Main Results:

  • Mixed quantum-classical methods accurately reproduce average nuclear motion initiated on a single electronic state.
  • These methods fail to capture nuclear motion induced by electronic wavepackets along derivative coupling.
  • The failure is attributed to the inability to model quantum electronic coherence, a key aspect of attochemistry.

Conclusions:

  • Widely used mixed quantum-classical methods have limitations in simulating attochemical processes.
  • Accurate simulation of attochemistry requires methods that capture quantum electronic coherence.
  • Further development of theoretical methods is needed to fully exploit attochemistry's potential.