Non-equilibrium Dynamics of Tunnel-Coupled Superfluids, 1st ed. 2020 Relaxation to a Phase-Locked Equilibrium State in a One-Dimensional Bosonic Josephson Junction Springer Theses Series

The relaxation of isolated quantum many-body systems is a major unsolved problem of modern physics, which is connected to many fundamental questions. However, realizations of quantum many-body systems which are both well isolated from their environment and accessible to experimental study are scarce. In recent years, the field has experienced rapid progress, partly attributed to ultra-cold atoms.

This book presents the experimental study of a relaxation phenomenon occurring in a one-dimensional bosonic Josephson junction. The system consists of two 1D quasi Bose-Einstein condensates of ⁸⁷Rb, magnetically trapped on an atom chip. Using radio-frequency dressing, the author deforms a single harmonic trap, in which the atoms are initially condensed, into a double-well potential and realizes a splitting of the wave function. A large spatial separation and a tilt of the double-well enable the preparation of a broad variety of initial states by precisely adjusting the initial population and relative phase of the two wave packets, while preserving the phase coherence. By re-coupling the two wave packets, the author investigates tunneling regimes such as Josephson (plasma) oscillations and macroscopic quantum self-trapping. 

Nominated as an outstanding Ph.D. thesis by the Atominstitut, TU Wien, Vienna, Austria

Experimental demonstration of a new physical phenomenon that challenges our understanding of statistical mechanics

Exhaustive experimental investigation of the phenomenon opening the way to further theoretical contributions