Relaxation Dynamics of Photocarriers in One-Dimensional Mott Insulators Coupled to Phonons

Matsueda, Hiroaki; Sota, Shigetoshi; Tohyama, Takami; Maekawa, Sadamichi

doi:10.1143/jpsj.81.013701

Cited by 43 publications

(46 citation statements)

References 14 publications

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“…After this process, a complete nonadiabatic decoupling between vibrational and electronic degrees of freedom was reported 14 . Similar results for the half-filled case were reported elsewhere 18 . In this publication, we present a detailed densitymatrix renormalization-group (DMRG)…”

Section: Introductionsupporting

confidence: 91%

“…Theoretical investigations of the photogenerated dynamics of organic compounds have also been reported [9][10][11][12][13][14][15][16][17][18] . Using a time-dependent Lanczos approach, the dynamics of (EDO-TTF) 2 PF 6 induced by a timedependent multi-cycle electrical field, studied the efficiency of the partial melting of the 2k F CO ground the state in the presence of different lattice potentials 12 .…”

Section: Introductionmentioning

confidence: 99%

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Photoexcitation of electronic instabilities in one-dimensional charge-transfer systems

et al. 2014

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We investigate the real-time dynamics of photoexcited electronic instabilities in a charge-transfer system model, using the time-dependent density matrix renormalization group method. The model of choice was the quarter-filled one-dimensional extended Peierls-Hubbard Hamiltonian interacting with classical few-cycle electromagnetic radiation. The results show that only one electronic instability drives the main features of the photogenerated time-dependent behavior. Indeed, the photoresponse of the system shows a large enhancement of the 4kF (bond and charge) instability whereas the 2kF state remains largely unaffected. This conclusion holds regardless of the nature of the optical excitations and whether the system is perturbed resonantly or not. Our results suggest potential applications of charge-transfer systems with slow phononic dynamics as optoelectronic switching devices.

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Section: Introductionsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Photoexcitation of electronic instabilities in one-dimensional charge-transfer systems

et al. 2014

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“…In the following we will show that a multiphonon emission can be a viable recombination mechanism in 1D organic Mott insulators, somewhat specific to organic materials with energetic intramolecular vibrations and strong electron-phonon coupling [17,18]. The mechanism bears similarity with recently proposed multiphonon exciton decay in semiconducting carbon nanotubes [19], while in standard semiconductors such a scenario seems to be inefficient [20].…”

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confidence: 58%

Exciton recombination in one-dimensional organic Mott insulators

2015

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We present a theory for the recombination of (charged) holons and doublons in one-dimensional organic Mott insulators, which is responsible for the decay of the photoexcited state. Due to the charge-spin separation, the dominant mechanism for recombination at low density of charges involves a multiphonon emission. We show that a reasonable coupling to phonons is sufficient to explain the fast recombination observed by pumpprobe experiments in ET-F 2 TCNQ, whereby we can also account for the measured pressure dependence of the recombination rate. Introduction. Femtosecond pump-probe spectroscopy is a powerful probe for the charge relaxation and thermalization phenomena in complex materials. These measurements can directly address and unveil the role of strong electron correlations, as well as the coupling to phonon degrees of freedom. Materials that behave as Mott insulators due to strong electron Coulomb repulsion contain all the latter physics, and are therefore of high theoretical and experimental interest. It has been observed that photoinduced charges decay within the picosecond range, i.e., well within the experimental resolution, but on the other hand orders of magnitude faster than in clean semiconductors with similar energy gaps.So far two classes of Mott insulators, investigated by pumpprobe spectroscopy, revealed similar behavior. These are the layered undoped cuprates La 2 CuO 4 and Nd 2 CuO 4 [1-3], and the quasi-one-dimensional (1D) organic Mott insulators of the tetracyanoquinodimethane (TCNQ) family [4], in particular, ET-F 2 TCNQ [4][5][6][7], which will be the focus of our study. Both undoped cuprates and ET-F 2 TCNQ reveal ultrafast picosecond charge recombination with some similarities: (a) The charged carriers created by the pump pulse above the Mott-Hubbard (MH) gap are holons and doublons, and their recombination requires the distribution of a large energy quantum (the MH gap ∼ 1 eV) into several final excitations with smaller energy 0 . At low density of charges candidates for recipient bosons can be spin or phonon excitations. (b) The decay is exponential in time. This excludes bi-and higher-molecular processes involving inelastic collision of several "free" charge carriers, and implicitly reveals the existence of an intermediate bound state of a holon and a doublon (the MH exciton). In this respect a different observation has been obtained on Ca 2 CuO 3 from the 1D cuprate family, which is known to have negligible excitonic effects [8] and thus shows a nonexponential decay [9].From a theoretical viewpoint the challenge of understanding the charge recombination has analogies with the decay of the double occupancy in ultracold bosons [10] and fermions [11,12] in optical lattices, where the decay rate exhibits an exponential dependence on the ratio of the Coulomb repulsion U and the typical excitation's energy scale 0 . In the latter case the system can be described by

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“…27-29, the non-equilibrium dynamics of one or two polarons in the Holstein model was investigated with a time-dependent exact diagonalization method. As for many-electron problems, previous works have investigated systems with classical phonons 31 or quantum phonons 32 in one-dimension. Many-electron problems in two-dimensional systems have been studied with an exact diagonalization method for the Holstein-Hubbard model 33 or with a weak-coupling perturbation theory for the Holstein model.…”

Section: 22mentioning

confidence: 99%

Interaction quench in the Holstein model: Thermalization crossover from electron- to phonon-dominated relaxation

et al. 2015

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We study the relaxation of the Holstein model after a sudden switch-on of the interaction by means of the nonequilibrium dynamical mean field theory, with the self-consistent Migdal approximation as an impurity solver. We show that there exists a qualitative change in the thermalization dynamics as the interaction is varied in the weak-coupling regime. On the weaker interaction side of this crossover, the phonon oscillations are damped more rapidly than the electron thermalization timescale, as determined from the relaxation of the electron momentum distribution function. On the stronger interaction side, the relaxation of the electrons becomes faster than the phonon damping. In this regime, despite long-lived phonon oscillations, a thermalized momentum distribution is realized temporarily. The origin of the "thermalization crossover" found here is traced back to different behaviors of the electron and phonon self-energies as a function of the electron-phonon coupling. In addition, the importance of the phonon dynamics is demonstrated by comparing the self-consistent Migdal results with those obtained with a simpler Hatree-Fock impurity solver that neglects the phonon self-energy. The latter scheme does not properly describe the evolution and thermalization of isolated electron-phonon systems.

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Relaxation Dynamics of Photocarriers in One-Dimensional Mott Insulators Coupled to Phonons

Cited by 43 publications

References 14 publications

Photoexcitation of electronic instabilities in one-dimensional charge-transfer systems

Photoexcitation of electronic instabilities in one-dimensional charge-transfer systems

Exciton recombination in one-dimensional organic Mott insulators

Interaction quench in the Holstein model: Thermalization crossover from electron- to phonon-dominated relaxation

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