Coherent vibrational energy transfer along a peptide helix

Based on the operatorial formulation of the perturbation theory, the exciton-phonon problem is revisited for investigating exciton-mediated energy flow in a finite-size lattice. Within this method, the exciton-phonon entanglement is taken into account through a dual dressing mechanism so that exciton and phonons are treated on an equal footing. In a marked contrast with what happens in an infinite lattice, it is shown that the dynamics of the exciton density is governed by several time scales. The density evolves coherently in the short-time limit whereas a relaxation mechanism occurs over intermediated time scales. Consequently, in the long-time limit, the density converges toward a nearly uniform distributed equilibrium distribution. Such a behavior results from quantum decoherence that originates in the fact that the phonons evolve differently depending on the path followed by the exciton to tunnel along the lattice. Although the relaxation rate increases with the temperature and with the coupling, it decreases with the lattice size, suggesting that the decoherence is inherent to the confinement.

Section: Introductionmentioning

confidence: 99%

Energy transfer in finite-size exciton-phonon systems: Confinement-enhanced quantum decoherence

Pouthier

2012

“…The coefficients provide the instantaneous populations of the sites and the instantaneous interstate coherences. 24 To compute observables, the statistical density matrix must be computed by averaging the instantaneous values c * m (t)c n (t) over trajectories describing the ensemble. Such a procedure yields the statistical density matrix…”

Section: The Vibrational Dynamicsmentioning

confidence: 99%

Two-dimensional infrared spectral signature and hydration of the oxalate dianion

Kuroda

Hochstrasser

2011

Ultrafast vibrational spectra of the aqueous oxalate ion in the region of its carboxylate asymmetric stretch modes show novel relaxation processes. Two-dimensional infrared vibrational echo spectra and the vibrational dynamics obtained from them along with measurements of the anisotropy decay provide a picture in which the localization of the oxalate vibrational excitation onto the carboxylate groups occurs in ~450 fs. Molecular dynamics simulations are used to characterize the vibrational dynamics in terms of dihedral angle motion between the two carboxylate planes and solvation dynamics. The localization of the oxalate vibrational excitation onto the carboxylates is induced by the fluctuations in the carboxylate vibrational frequencies which are shown by theory and experiment to have a similar correlation time as the anisotropy decay.

“…From a theoretical point of view, the intramolecular vibrational energy flow in biomolecules has also received a great deal of attention 2, 28 through different approaches including harmonic theories, 8,26,[29][30][31][32][33] molecular dynamics (MD) simulations, 28,[34][35][36][37][38][39][40][41][42][43][44][45][46] coarse-grained models, 33,47 and quantum methods. 21,[48][49][50][51][52][53] Despite this diversity of theoretical treatments, comparison between experimental and theoretical studies is still unsatisfactory because it faces the major difficulty that whereas experiments provide information on the energy transport spectroscopically from the vibrational modes which are active in the technique employed, most of the theoretical treatments discuss the energy flow in terms of residuebased models which, although shown to be quite useful in describing the spatial evolution of the energy, 38,39,41,44 are not well suited for direct comparison with observed data since the residues are not the experimentally active units.…”

Section: Introductionmentioning

confidence: 99%

A method for analyzing the vibrational energy flow in biomolecules in solution

Soler

Bastida

Farag

et al. 2011

A method is proposed to analyze the intra- and intermolecular vibrational energy flow occurring in biomolecules in solution during relaxation processes. It is based on the assumption that the total energy exchanged between the vibrational modes is minimal and the global process is essentially statistical. This statistical minimum flow method is shown to provide very useful information about the amount and the rate at which energy is transferred between the individual vibrations of the molecule. To demonstrate the performance of the method, an application is made to the relaxation of the amide I mode of N-methylacetamide-d in aqueous D(2)O solution which yields a detailed quantitative description of the process.