Magnetic field-free braiding and nontrivial fusion of Majorana bound states in high-temperature planar Josephson junctions
Abstract
Demonstration of non-Abelian statistics of zero-energy Majorana bound states (MBS) is crucial for long-sought-after decoherence-free topological quantum computing. The ability to move the MBS on a two-dimensional platform such as a planar Josephson junction is practically constrained by a fixed direction of applied magnetic field. In addition, the detrimental effects of the magnetic field on proximity-induced superconductivity in semiconductor-superconductor heterostructures is an outstanding problem for the realization of topological superconductivity. Here we show that these problems can be solved in a planar Josephson junction coupled to a skyrmion crystal, which generates the MBS without the need of any external magnetic field, phase biasing, and Rashba spin-orbit coupling. Using a high-temperature superconductor having $d$-wave pairing symmetry, we confirm that our planar junction can support the MBS at high temperatures. We propose protocols for performing non-trivial fusion, exchange and non-Abelian braiding of multiple MBS in our field-free platforms. The proposed geometries and MBS movement protocols open a path towards successful experimental detection of the MBS via confirmation of their non-Abelian statistics.