Zusammenfassung der Projektergebnisse

In this project, we investigated the effects of the couplings between electronic, vibrational, and rotational degrees of freedom on quantum dynamics of various molecular processes. The proposal mainly involves three lines of research, namely, (i) non-adiabatic quantum dynamics at lightinduced conical intersections (LICIs), (ii) effect of nuclear permutation symmetry on dynamical localization in symmetric molecules, and (iii) phonon-driven vibrational relaxation of adsorbates on surfaces. In the first subproject, we developed a topological approach to fully unwind the molecular wavefunction at a LICI, allowing to disentangle the effects of the geometric phase (GP) and nonadiabatic electronic transitions. Leaning on the fingerprints of the GP in molecular observables, this technique provides a clear recipe for the search of LICIs in molecules. To corroborate our theoretical/numerical findings, a simple corresponding experimental scheme, dealing with laser dissociation of D2+ molecules, has been proposed. The extension of the developed approach to other types of electronic degeneracies, such as glancing intersections, has also been explored. In the second subproject, we scrutinized the effect of nuclear permutation symmetry on dynamical localization of vibrational or electronic densities in highly symmetric molecules, viz. those involving identical (indistinguishable) molecular structures or configurations. Using rigorous group-theoretic analysis, we show that nuclear permutation symmetry engenders entanglement between different molecular degrees of freedom, which subsequently leads to complete quenching of (dynamical) localization on identical molecular configurations−an observation that is in sharp contradiction with the textbook view of iconic quantum processes and the interpretation of well known experiments. These include umbrella inversion of ammonia, electronic Kekulé dynamics in benzene, and electron-localization following laser dissociation of H2+ Molecules. The third subproject is devoted to the development of approximate wavefunction approaches for phonon-induced vibrational relaxation of adsorbates at surfaces. A process which cannot be handled with standard wavefunction methods, due to the curse of dimensionality. To alleviate the exponential scaling of the latter, we developed two different methods, namely, ‘the hierarchical effective mode approach’ and ‘ the quantum tier model’. Both lead to a drastic reduction of the dimension of the adsorbatesurface vibrational space. These approaches have been successfully applied to the decay of H-Si (D-Si) vibrations on a fully H(D)-covered silicon surface, which is modeled with a phonon bath of more than two thousand oscillators. These approximate yet accurate numerical schemes embody most dissipative and (de)coherent effects, which cannot be accounted for with the widely used ‘reduced density matrix formalism’, and thus provide more reliable estimates of the adsorbate vibrational lifetimes.

Projektbezogene Publikationen (Auswahl)

• Isotopic effects in vibrational relaxation dynamics of H on a Si(100) surface. The Journal of Chemical Physics, 147(14).
  Bouakline, F.; Lorenz, U.; Melani, G.; Paramonov, G. K. & Saalfrank, P.
  
• “Fingerprints of light-induced conical intersections in diatomics”, Poster, 25th colloquium on high resolution spectroscopy, Helsinki, Finland, August 2017
  F. Bouakline
  
• Unambiguous Signature of the Berry Phase in Intense Laser Dissociation of Diatomic Molecules. The Journal of Physical Chemistry Letters, 9(9), 2271-2277.
  Bouakline, Foudhil
  
• A quantum-mechanical tier model for phonon-driven vibrational relaxation dynamics of adsorbates at surfaces. The Journal of Chemical Physics, 150(24).
  Bouakline, F.; Fischer, E. W. & Saalfrank, P.
  
• “Non-adiabatic quantum dynamics at light-induced conical intersections", Invited talk, Mini-symposium of theoretical chemistry, University of Potsdam, April 2019
  F. Bouakline
  
• A hierarchical effective mode approach to phonon-driven multilevel vibrational relaxation dynamics at surfaces. The Journal of Chemical Physics, 153(6).
  Fischer, Eric W.; Werther, Michael; Bouakline, Foudhil & Saalfrank, Peter
  
• Does nuclear permutation symmetry allow dynamical localization in symmetric double-well achiral molecules?. The Journal of Chemical Physics, 152(24).
  Bouakline, Foudhil
  
• Is it really possible to control aromaticity of benzene with light?. Physical Chemistry Chemical Physics, 22(27), 15401-15412.
  Bouakline, F. & Tremblay, J. C.
  
• “On the role of quantum statistics on electron dynamics in benzene", Group seminar, Institute of Chemistry, University of Potsdam, July 2020
  F. Bouakline
  
• Quantum Chemistry Treatment of Silicon-Hydrogen Bond Rupture by Nonequilibrium Carriers in Semiconductor Devices. Physical Review Applied, 16(1).
  Jech, Markus; El-Sayed, Al-Moatasem; Tyaginov, Stanislav; Waldhör, Dominic; Bouakline, Foudhil; Saalfrank, Peter; Jabs, Dominic; Jungemann, Christoph; Waltl, Michael & Grasser, Tibor
  
• Seemingly asymmetric atom-localized electronic densities following laser-dissociation of homonuclear diatomics. The Journal of Chemical Physics, 154(23).
  Bouakline, Foudhil & Saalfrank, Peter
  
• Umbrella inversion of ammonia redux. Physical Chemistry Chemical Physics, 23(36), 20509-20523.
  Bouakline, Foudhil
  
• “Manifestations of quantum effects in molecular reaction dynamics and spectroscopy", institute colloquium, Institute of Chemistry, University of Potsdam, July 2021
  F. Bouakline
  
• Non-Markovian vibrational relaxation dynamics at surfaces. The Journal of Chemical Physics, 156(21).
  Fischer, Eric W.; Werther, Michael; Bouakline, Foudhil; Grossmann, Frank & Saalfrank, Peter
  
• “On the role of nuclear permutation symmetry in quantum molecular dynamics", invited talk, Stereodynamics 2022, Rethymno, Crete, Greece, November 2022
  F. Bouakline
  
• “On the role of nuclear-spin statistics in quantum molecular dynamics", invited seminar, Quantum Dynamics Seminar, MPIPKS, Dresden, June 2022
  F. Bouakline
  
• Habilitation thesis ‘Manifestations of Quantum-Mechanical Effects in Molecular Reaction Dynamics’, 316 pages, PPN: 1859300073 (Universität Potsdam, 2023)
  Foudhil Bouakline
  
• “Manifestations of quantum-mechanical effects in molecular reaction dynamics", Habilitation thesis defense, University of Potsdam
  F. Bouakline