Out-of-equilibrium dynamics in 1D Bose gases / Dynamique hors équilibre des gaz bosoniques 1D

Schemmer, Maximilian

22 March 2019

Cette thèse contient plusieurs études expérimentales centrées sur la dynamique des bosons dans une dimension (1D). En utilisant une expérience de type puce atomique, nous créons des géométries de piègage très allongées pour des atomes de 87Rb. Cela conduit à geler deux dimensions et à créer un gaz 1D avec des interactions de contact qui est décrit par le modèle de Lieb-Liniger. Le manuscrit contient trois études expérimentales indépendantes: La première étude traite de la dynamique hors équilibre suite à une trempe des interactions. Nous observons l'évolution temporelle des modes de Bogoliubov comprimés et montrons que cette dynamique continue sur des temps qui ne seraient pas observable sur la fonction de corrélation d'ordre un.La deuxième étude montre que les pertes à trois-corps refroidissent un gaz de Bose 1D dans le régime quasi-condensat. Ce travail est accompagné d'une étude théorique qui prédit ce refroidissement pour les pertes à j-corps.La troisième étude est la première étude expérimentale d'une nouvelle théorie des systèmes intégrables, nommé HydroDynamics Généralisé (HDG).Nous montrons que HDG est la seule théorie <<simple>> qui décrit correctement les résultats expérimentaux.En particulier, l’approche de l'HydroDynamique Conventiennelle (HDC) ne reproduit pas l’observation expérimentale. Contrairement au HDG, HDC ne prend pas en compte l’intégrabilité du système. / This thesis contains several experimental studies centered around the dynamics of bosons in one dimension (1D). With the use of an atomchip setup we create very elongated trapping geometries for $^{87}$Rb. This leads to the freeze-out of two dimensions and the creation of a 1D gas with contact interactions, described the Lieb-Liniger model. The manuscript contains three independent experimental studies: The first one investigates the out-of-equilibrium dynamics after an interaction quench. We observe the time evolution of squeezed Bogoliubov modes and show that this dynamics continues on times which cannot be observed on the first order correlation function.The second study shows that three-body losses cool a 1D Bose gas in the quasi-condensate regime. This work is accompanied by a theoretical study, which predicts this cooling for $j$-body losses.The third study consists of the first experimental study of a new theory in integrable systems -- the Generalized HydroDynamics (GHD).We show that GHD is the only "simple" theory which correctly describes the experimental results.In particular, the Conventional HydroDynamics (CHD) approach fails to reproduce the experimental observation. In contrast to GHD, CHD does not take into account the integrability of the system.

Atomes froids

Expérience puce atomique

Système unidimensionnel

Dynamique hors d'équilibre

Système intégrable

Cold atoms

Atom chip experiment

Onedimensional system

Out-Of-Equilibrium dynamics

Integrable system

530

530.12

Ultrafast exciton relaxation in quasi-one-dimensional perylene derivatives / Ultraschnelle Relaxation von Exzitonen in quasi-eindimensionalen Perylenderivaten

Engel, Egbert

07 February 2006

This thesis deals with exciton relaxation processes in thin polycrystalline films and matrix-isolated molecules of the perylene derivatives PTCDA (3,4,9,10-perylenetetracarboxylic dianhydride) and MePTCDI (N,N'-dimethylperylene-3,4,9,10-dicarboximide). Using femtosecond pump-probe spectroscopy, transient absorption spectra, excitonic relaxation in the lowest excited state subsequent to excitation, and exciton-exciton interaction and annihilation at high excitation densities have been addressed. Transient absorption spectroscopy in the range 1.2eV-2.6eV has been applied to thin polycrystalline films of PTCDA and MePTCDI and to solid solutions of PTCDA and MePTCDI molecules (monomers) in a SiO2 matrix. We are able to ascribe the respective signal contributions to ground state bleaching, stimulated emission, and excited state absorption. Both systems exhibit broad excited-state absorption features below 2.0eV, with dominant peaks between 1.8eV and 2.0eV. The monomer spectra can be consistently explained by the results of quantum-chemical calculations on single molecules, and the respective experimental polarization anisotropies for the two major transitions agree with the calculated polarizations. Dimer calculations allow to qualitatively understand the trends visible in the experimental results from monomers to thin films. The broad excited state absorption band between 1.8eV and 2.0eV allows to probe the population dynamics in the first excited state of thin films. We show that excitons created at the Gamma point relax towards the border of the Brillouin zone on a 100fs time scale in both systems. Excitonic relaxation is accelerated by increase of temperature and/or excitation density, which is attributed to stimulated phonon emission during relaxation in k-space. Lower and upper limits of the intraband relaxation time constants are 25fs (resolution limit) and 250fs (100fs) for PTCDA (MePTCDI). These values agree with the upper limit for the intraband relaxation time of 10ps, evaluated from time-resolved luminescence measurements. While the luminescence anisotropy is in full accordance with the predictions made by a luminescence anisotropy model being consistent with the exciton model of Davydov-split states, the pump-probe anisotropy calls for an explanation beyond the models presently available. At excitation densities 10^(19)cm^(-3), the major de-excitation mechanism for the relaxed excitons is exciton-exciton annihilation, resulting in a strongly reduced exciton life time. Three different models for the microscopic behavior have been tested: a diffusion-limited annihilation model in both three and one dimensions (with diffusion constant D as fit parameter) as well as a long-range single-step Förster-type annihilation model (with Förster radius RF as fit parameter). For PTCDA, the latter two, being structurally equivalent, allow to fit a set of multiexponential decay curves for multiple initial exciton densities with high precision. In contrast, the three-dimensional diffusion-limited model is clearly inferior. For all three models, we extract annihilation rates, diffusion constants and diffusion lengths (or Förster radii), for both room and liquid helium temperature. Temperature dependence and orders of magnitude of the obtained parameters D or RF correspond to the expectations. For MePTCDI, the 1D and the Förster model are in good agreement for a smaller interval of excitation densities. For a initial exciton densities higher than 5 x 10^(19)cm^(-3), the 3D model performs significantly better than the other two.

Anisotropie

Davydov splitting

Exziton-Exziton-Annihilation

Exzitonen

Exzitonendiffusion

Frenkel-Exziton

Organische Halbleiter

PTCDA

Perylen-Derivate

Pump-Probe

Quasi-eindimensionale Struktur

Ultrakurzzeitdynamik

Ultrakurzzeitspektroskopie

Anisotropy

Davydov components

Davydov splitting

Exciton diffusion

Exciton-exciton annihilation

Excitons

Frenkel exciton

Organic semiconductors

PTCDA

Perylene derivatives

Quasi-onedimensional structure

Ultrafast dynamics

Ultrafast spectroscopy

ddc:530

rvk:UP 3710

Anisotropie

Exziton

Frenkel-Exziton

Organischer Halbleiter

Perylenderivate

Perylendianhydrid

Pump-Probe-Technik

Ultrakurzzeitspektroskopie

Ultrafast exciton relaxation in quasi-one-dimensional perylene derivatives

Engel, Egbert

30 January 2006

This thesis deals with exciton relaxation processes in thin polycrystalline films and matrix-isolated molecules of the perylene derivatives PTCDA (3,4,9,10-perylenetetracarboxylic dianhydride) and MePTCDI (N,N'-dimethylperylene-3,4,9,10-dicarboximide). Using femtosecond pump-probe spectroscopy, transient absorption spectra, excitonic relaxation in the lowest excited state subsequent to excitation, and exciton-exciton interaction and annihilation at high excitation densities have been addressed. Transient absorption spectroscopy in the range 1.2eV-2.6eV has been applied to thin polycrystalline films of PTCDA and MePTCDI and to solid solutions of PTCDA and MePTCDI molecules (monomers) in a SiO2 matrix. We are able to ascribe the respective signal contributions to ground state bleaching, stimulated emission, and excited state absorption. Both systems exhibit broad excited-state absorption features below 2.0eV, with dominant peaks between 1.8eV and 2.0eV. The monomer spectra can be consistently explained by the results of quantum-chemical calculations on single molecules, and the respective experimental polarization anisotropies for the two major transitions agree with the calculated polarizations. Dimer calculations allow to qualitatively understand the trends visible in the experimental results from monomers to thin films. The broad excited state absorption band between 1.8eV and 2.0eV allows to probe the population dynamics in the first excited state of thin films. We show that excitons created at the Gamma point relax towards the border of the Brillouin zone on a 100fs time scale in both systems. Excitonic relaxation is accelerated by increase of temperature and/or excitation density, which is attributed to stimulated phonon emission during relaxation in k-space. Lower and upper limits of the intraband relaxation time constants are 25fs (resolution limit) and 250fs (100fs) for PTCDA (MePTCDI). These values agree with the upper limit for the intraband relaxation time of 10ps, evaluated from time-resolved luminescence measurements. While the luminescence anisotropy is in full accordance with the predictions made by a luminescence anisotropy model being consistent with the exciton model of Davydov-split states, the pump-probe anisotropy calls for an explanation beyond the models presently available. At excitation densities 10^(19)cm^(-3), the major de-excitation mechanism for the relaxed excitons is exciton-exciton annihilation, resulting in a strongly reduced exciton life time. Three different models for the microscopic behavior have been tested: a diffusion-limited annihilation model in both three and one dimensions (with diffusion constant D as fit parameter) as well as a long-range single-step Förster-type annihilation model (with Förster radius RF as fit parameter). For PTCDA, the latter two, being structurally equivalent, allow to fit a set of multiexponential decay curves for multiple initial exciton densities with high precision. In contrast, the three-dimensional diffusion-limited model is clearly inferior. For all three models, we extract annihilation rates, diffusion constants and diffusion lengths (or Förster radii), for both room and liquid helium temperature. Temperature dependence and orders of magnitude of the obtained parameters D or RF correspond to the expectations. For MePTCDI, the 1D and the Förster model are in good agreement for a smaller interval of excitation densities. For a initial exciton densities higher than 5 x 10^(19)cm^(-3), the 3D model performs significantly better than the other two.

info:eu-repo/classification/ddc/530

ddc:530