Your search keyword '"strong interactions"' showing total 5 results

1. Spectral properties and breathing dynamics of a few-body Bose–Bose mixture in a 1D harmonic trap

Author

Maxim Pyzh, Sven Krönke, Christof Weitenberg, and Peter Schmelcher

Subjects

collective excitations, breathing mode, low-dimensional systems, few-body systems, strong interactions, bosonic mixtures, Science, Physics, QC1-999

Abstract

We investigate a few-body mixture of two bosonic components, each consisting of two particles confined in a quasi one-dimensional harmonic trap. By means of exact diagonalization with a correlated basis approach we obtain the low-energy spectrum and eigenstates for the whole range of repulsive intra- and inter-component interaction strengths. We analyse the eigenvalues as a function of the inter-component coupling, covering hereby all the limiting regimes, and characterize the behaviour in-between these regimes by exploiting the symmetries of the Hamiltonian. Provided with this knowledge we study the breathing dynamics in the linear-response regime by slightly quenching the trap frequency symmetrically for both components. Depending on the choice of interactions strengths, we identify 1 to 3 monopole modes besides the breathing mode of the centre of mass coordinate. For the uncoupled mixture each monopole mode corresponds to the breathing oscillation of a specific relative coordinate. Increasing the inter-component coupling first leads to multi-mode oscillations in each relative coordinate, which turn into single-mode oscillations of the same frequency in the composite-fermionization regime.

Published

2018

2. Mobile spin impurity in an optical lattice

Author

C W Duncan, F F Bellotti, P Öhberg, N T Zinner, and M Valiente

Subjects

strong interactions, optical lattice, one dimension, impurity, Science, Physics, QC1-999

Abstract

We investigate the Fermi polaron problem in a spin-1/2 Fermi gas in an optical lattice for the limit of both strong repulsive contact interactions and one dimension. In this limit, a polaronic-like behaviour is not expected, and the physics is that of a magnon or impurity. While the charge degrees of freedom of the system are frozen, the resulting tight-binding Hamiltonian for the impurity’s spin exhibits an intriguing structure that strongly depends on the filling factor of the lattice potential. This filling dependency also transfers to the nature of the interactions for the case of two magnons and the important spin balanced case. At low filling, and up until near unit filling, the single impurity Hamiltonian faithfully reproduces a single-band, quasi-homogeneous tight-binding problem. As the filling is increased and the second band of the single particle spectrum of the periodic potential is progressively filled, the impurity Hamiltonian, at low energies, describes a single particle trapped in a multi-well potential. Interestingly, once the first two bands are fully filled, the impurity Hamiltonian is a near-perfect realisation of the Su–Schrieffer–Heeger model. Our studies, which go well beyond the single-band approximation, that is, the Hubbard model, pave the way for the realisation of interacting one-dimensional models of condensed matter physics.

Published

2017

3. Tunable self-assembled spin chains of strongly interacting cold atoms for demonstration of reliable quantum state transfer

Author

N J S Loft, O V Marchukov, D Petrosyan, and N T Zinner

Subjects

cold atoms, spin chains, one-dimensional physics, strong interactions, quantum state transfer, 6785-d, Science, Physics, QC1-999

Abstract

We have developed an efficient computational method to treat long, one-dimensional systems of strongly interacting atoms forming self-assembled spin chains. Such systems can be used to realize many spin chain model Hamiltonians tunable by the external confining potential. As a concrete demonstration, we consider quantum state transfer in a Heisenberg spin chain and we show how to determine the confining potential in order to obtain nearly perfect state transfer.

Published

2016

4. Transport enhancement from incoherent coupling between one-dimensional quantum conductors

Author

J J Mendoza-Arenas, M T Mitchison, S R Clark, J Prior, D Jaksch, and M B Plenio

Subjects

spin current, transport enhancement, strong interactions, decoherence, energy dissipation, Science, Physics, QC1-999

Abstract

We study the non-equilibrium transport properties of a highly anisotropic two-dimensional lattice of $\text{spin}-\frac{1}{2}$ particles governed by a Heisenberg XXZ Hamiltonian. The anisotropy of the lattice allows us to approximate the system at finite temperature as an array of incoherently coupled one-dimensional chains. We show that in the regime of strong intrachain interactions, the weak interchain coupling considerably boosts spin transport in the driven system. Interestingly, we show that this enhancement increases with the length of the chains, which is related to superdiffusive spin transport. We describe the mechanism behind this effect, compare it to a similar phenomenon in single chains induced by dephasing, and explain why the former is much stronger.

Published

2014

5. Fermionization of two-component few-fermion systems in a one-dimensional harmonic trap

Author

E J Lindgren, J Rotureau, C Forssén, A G Volosniev, and N T Zinner

Subjects

cold atoms, strong interactions, low-dimensional systems, Science, Physics, QC1-999

Abstract

The nature of strongly interacting Fermi gases and magnetism is one of the most important and studied topics in condensed-matter physics. Still, there are many open questions. A central issue is under what circumstances strong short-range repulsive interactions are enough to drive magnetic correlations. Recent progress in the field of cold atomic gases allows one to address this question in very clean systems where both particle numbers, interactions and dimensionality can be tuned. Here we study fermionic few-body systems in a one dimensional harmonic trap using a new rapidly converging effective-interaction technique, plus a novel analytical approach. This allows us to calculate the properties of a single spin-down atom interacting with a number of spin-up particles, a case of much recent experimental interest. Our findings indicate that, in the strongly interacting limit, spin-up and spin-down particles want to separate in the trap, which we interpret as a microscopic precursor of one-dimensional ferromagnetism in imbalanced systems. Our predictions are directly addressable in current experiments on ultracold atomic few-body systems.

Published

2014