Steve Simon

Skyrmions in the Moore-Read state at nu=5/2

(2009)

Authors:

Arkadiusz Wojs, Gunnar Moller, Steven H Simon, Nigel R Cooper

Topological quantum computing with read-rezayi states

Physical Review Letters 103:16 (2009)

Authors:

L Hormozi, NE Bonesteel, SH Simon

Abstract:

Read-Rezayi fractional quantum Hall states are among the prime candidates for realizing non-Abelian anyons which, in principle, can be used for topological quantum computation. We present a prescription for efficiently finding braids which can be used to carry out a universal set of quantum gates on encoded qubits based on anyons of the Read-Rezayi states with k>2, k≠4. This work extends previous results which only applied to the case k=3 (Fibonacci) and clarifies why, in that case, gate constructions are simpler than for a generic Read-Rezayi state. © 2009 The American Physical Society.

Numerical analysis of quasiholes of the moore-read wave function

Physical Review Letters 103:7 (2009)

Authors:

M Baraban, G Zikos, N Bonesteel, SH Simon

Abstract:

We demonstrate numerically that non-Abelian quasihole (qh) excitations of the ν=5/2 fractional quantum Hall state have some of the key properties necessary to support quantum computation. We find that as the qh spacing is increased, the unitary transformation which describes winding two qh's around each other converges exponentially to its asymptotic limit and that the two orthogonal wave functions describing a system with four qh's become exponentially degenerate. We calculate the length scales for these two decays to be ξU2.70 and ξE2.30, respectively. Additionally, we determine which fusion channel is lower in energy when two qh's are brought close together. © 2009 The American Physical Society.

S3 Quantum Hall Wavefunctions

(2009)

Authors:

Steven H Simon, EH Rezayi, N Regnault

Itinerant ferromagnetism in an atom trap

Physical Review B - Condensed Matter and Materials Physics 79:22 (2009)

Authors:

I Berdnikov, P Coleman, SH Simon

Abstract:

We propose an experiment to explore the magnetic phase transitions in interacting fermionic Hubbard systems and describe how to obtain the ferromagnetic phase diagram of itinerant-electron systems from these observations. In addition, signatures of ferromagnetic correlations in the observed ground states are found: for large trap radii (trap radius RT >4, in units of coherence length ξ), ground states are topological in nature-a "skyrmion" in two dimension, and a "hedgehog" in three dimension. © 2009 The American Physical Society.