Abstract
Majorana fermions are predicted to arise at the ends of nanowire devices which combine superconductivity, strong spin-orbit coupling and an external magnetic field. By manipulating networks of these devices with suitable gating, it has been suggested that braiding operations may be performed which act as logic operations, suitable for quantum computation. However, the unavoidable misalignment of the magnetic field in any realistic device geometry has raised questions about the feasibility of such braiding. In this paper, we numerically simulate braiding operations in devices with Y-junction and tuning fork geometries using an experimentally motivated nanowire model. We study how the static and dynamical features vary with geometric parameters and identify parameter choices that optimise the probability of a successful braid. Notably, we find that there is an optimal Y-junction half-angle (about 20 degrees for our parameter values), which balances two competing mechanisms that reduce the energy gap to excitations. In addition, we find that a tuning fork geometry has significant advantages over a Y-junction geometry, as it substantially reduces the effect of dynamical phase oscillations that complicate the braiding process. Our results suggest that performing a successful braid is in principle possible with such devices, and lies within experimental reach.
Highlights
Bound states of Majorana fermions are believed to exhibit non-Abelian statistics [1,2,3,4,5,6,7,8,9] and so offer the exciting possibility of realizing a topological quantum computer [10,11]
We study the braiding of a pair of Majorana fermions in a realistic nanowire device, which, if reproduced experimentally, could provide one such unambiguous signature
We numerically study the feasibility of such a braid in a realistic nanowire system
Summary
Bound states of Majorana fermions are believed to exhibit non-Abelian statistics [1,2,3,4,5,6,7,8,9] and so offer the exciting possibility of realizing a topological quantum computer [10,11]. We study the braiding of a pair of Majorana fermions in a realistic nanowire device, which, if reproduced experimentally, could provide one such unambiguous signature. Nanowires based on this model have been developed by several groups, both by using direct epitaxial growth and by depleting regions of a two-dimensional electron gas to leave an effectively one-dimensional (1D) channel [16,17,18,19,20,21,22,23,24,25,26,27,28] Many of these experiments have reported transport signatures consistent with the existence of MZMs: Notably, a MZM should lead to a robust zero-bias conductance peak quantised to 2e2/h [31,32] ( disorder and finite-temperature effects may disguise this [33]). VI, we summarize our results and provide some concluding remarks
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