Tunneling of trapped-atom Bose condensates

TL;DR

This paper models the tunneling dynamics of trapped-atom Bose-Einstein condensates in a double-well trap using the Gross-Pitaevskii equation, revealing complex oscillation modes including self-trapping and inverted pendulum behaviors.

Contribution

It introduces a Hamiltonian framework for Bose condensate tunneling that uncovers novel oscillation modes beyond traditional Josephson effects.

Findings

Identification of inverted pendulum oscillations with average angle 

Discovery of macroscopic quantum self-trapping phenomena

Rich set of tunneling modes surpassing superconductor Josephson junctions

Abstract

We obtain the dynamics in number and phase difference, for Bose condensates that tunnel between two wells of a double-well atomic trap, using the (nonlinear) Gross-Pitaevskii equation.The dynamical equations are of the canonical form for the two conjugate variables, and the Hamiltonian corresponds to that of a momentum-shortened pendulum, supporting a richer set of tunneling oscillation modes than for a superconductor Josephson junction, that has a fixed-length pendulum as a mechanical model. Novel modes include "inverted pendulum" oscillations with an average angle of \pi; and oscillations about a self-maintained population imbalance that we term "macroscopic quantum self-trapping". Other systems with this phase-number nonlinear dynamics include twocomponent (interconverting) condensates in a single harmonic trap, and He^{3}B superfluids in two containers connected by micropores.