We propose a topological qubit in which braiding and readout are mediated by the 4π Majorana-Josephson effect. The braidonium device consists of three Majorana nanowires that come together to make a tri-junction. In order to control the superconducting phase differences at the tri-junction, the nanowires are enclosed in a ring made of a conventional superconductor. In order to perform initialization/readout, one of the nanowires is coupled to a fluxonium qubit through a topological Josephson junction. We analyze how flux-based control and readout protocols can be used to demonstrate braiding and qubit operation for realistic materials and circuit parameters.
We study the differential conductance for charge tunneling into a
semiconductor wire--superconductor hybrid structure, which is actively
investigated as a possible scheme for realizing topological superconductivity
and Majorana zero modes. The calculations are done based on a tight-binding
model of the heterostructure using both a Blonder-Tinkham-Klapwijk approach and
a Keldysh non-equilibrium Green's function method. The dependence of various
tunneling conductance features on the coupling strength between the
semiconductor and the superconductor, the tunnel barrier height, and
temperature is systematically investigated. We find that treating the parent
superconductor as an active component of the system, rather than a passive
source of Cooper pairs, has qualitative consequences regarding the low-energy
behavior of the differential conductance. In particular, the presence of
sub-gap states in the parent superconductor, due to disorder and finite
magnetic fields, leads to characteristic particle-hole asymmetric features and
to the breakdown of the quantization of the zero-bias peak associated with the
presence of Majorana zero modes localized at the ends of the wire. The
implications of these findings for the effort toward the realization of
Majorana bound states with true non-Abelian properties are discussed.Comment: published version, 15+ pages, 12 figure
We study the low-energy physics of a one-dimensional array of superconducting quantum dots realized by proximity coupling a semiconductor nanowire to multiple superconducting islands separated by narrow uncovered regions. The effective electrostatic potential inside the quantum dots and the uncovered regions can be controlled using potential gates. By performing detailed numerical calculations based on effective tightbinding models, we find that multiple low-energy sub-gap states consisting of partially overlapping Majorana bound states emerge generically in the vicinity of the uncovered regions. Explicit differential conductance calculations show that a robust zero-bias conductance peak is not inconsistent with the presence of such states localized throughout the system, hence the observation of such a peak does not demonstrate the realization of well-separated Majorana zero modes. However, we find that creating effective potential wells in the uncovered regions traps pairs of nearby partially overlapping Majorana bound states, which become less separated and acquire a finite gap that protects the pair of Majorana zero modes localized at the ends of the system. This behavior persists over a significant parameter range, suggesting that proximitized quantum dot arrays could provide a platform for highly controllable Majorana devices. arXiv:1805.08119v2 [cond-mat.mes-hall]
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