Prof Dieter Jaksch

Numerical analysis of coherent many-body currents in a single atom transistor

Physical Review A - Atomic, Molecular, and Optical Physics 72:4 (2005)

Authors:

AJ Daley, SR Clark, D Jaksch, P Zoller

Abstract:

We study the dynamics of many atoms in the recently proposed single-atom-transistor setup [A. Micheli, A. J. Daley, D. Jaksch, and P. Zoller, Phys. Rev. Lett. 93, 140408 (2004)] using recently developed numerical methods. In this setup, a localized spin-12 impurity is used to switch the transport of atoms in a one-dimensional optical lattice: in one state the impurity is transparent to probe atoms, but in the other acts as a single-atom mirror. We calculate time-dependent currents for bosons passing the impurity atom, and find interesting many-body effects. These include substantially different transport properties for bosons in the strongly interacting (Tonks) regime when compared with fermions, and an unexpected decrease in the current when weakly interacting probe atoms are initially accelerated to a nonzero mean momentum. We also provide more insight into the application of our numerical methods to this system, and discuss open questions about the currents approached by the system on long time scales. © 2005 The American Physical Society.

Fault-tolerant dissipative preparation of atomic quantum registers with fermions

Physical Review A - Atomic, Molecular, and Optical Physics 72:3 (2005)

Authors:

A Griessner, AJ Daley, D Jaksch, P Zoller

Abstract:

We propose a fault-tolerant loading scheme to produce an array of fermions in an optical lattice of the high fidelity required for applications in quantum-information processing and the modeling of strongly correlated systems. A cold reservoir of fermions plays a dual role as a source of atoms to be loaded into the lattice via a Raman process and as a heat bath for sympathetic cooling of lattice atoms. Atoms are initially transferred into an excited motional state in each lattice site and then decay to the motional ground state, creating particle-hole pairs in the reservoir. Atoms transferred into the ground motional level are no longer coupled back to the reservoir, and doubly occupied sites in the motional ground state are prevented by Pauli blocking. This scheme has strong conceptual connections with optical pumping and can be extended to load high-fidelity patterns of atoms. © 2005 The American Physical Society.

Detection and characterization of multipartite entanglement in optical lattices

(2005)

Authors:

RN Palmer, C Moura Alves, D Jaksch

Efficient generation of graph states for quantum computation

New Journal of Physics (2005)

Authors:

SR Clark, C Moura Alves, DH Jaksch

The cold atom Hubbard toolbox

Annals of Physics 315:1 (2005) 52-79

Authors:

D Jaksch, P Zoller

Abstract:

We review recent theoretical advances in cold atom physics concentrating on strongly correlated cold atoms in optical lattices. We discuss recently developed quantum optical tools for manipulating atoms and show how they can be used to realize a wide range of many body Hamiltonians. Then, we describe connections and differences to condensed matter physics and present applications in the fields of quantum computing and quantum simulations. Finally, we explain how defects and atomic quantum dots can be introduced in a controlled way in optical lattice systems. © 2004 Elsevier Inc. All rights reserved.