Fault-tolerant quantum error correction with non-abelian anyons


Poulin, D. (2016). Fault-tolerant quantum error correction with non-abelian anyons. Perimeter Institute. https://pirsa.org/16110026


Poulin, David. Fault-tolerant quantum error correction with non-abelian anyons. Perimeter Institute, Nov. 02, 2016, https://pirsa.org/16110026


          @misc{ pirsa_16110026,
            doi = {},
            url = {https://pirsa.org/16110026},
            author = {Poulin, David},
            keywords = {Quantum Foundations},
            language = {en},
            title = {Fault-tolerant quantum error correction with non-abelian anyons},
            publisher = {Perimeter Institute},
            year = {2016},
            month = {nov},
            note = {PIRSA:16110026 see, \url{https://pirsa.org}}


Non-abelian anyons have drawn much interest due to their suspected existence in two-dimensional condensed matter systems and for their potential applications in quantum computation. In particular, a quantum computation can in principle be realized by braiding and fusing certain non-abelian anyons. These operations are expected to be intrinsically robust due to their topological nature. Provided the system is kept at a
temperature T lower than the spectral gap, the density of thermal excitations is suppressed by an exponential Boltzman factor. In contrast to the topological protection however, this thermal protection is not scalable: thermal excitations do appear at constant density for any non-zero temperature and so their presence is unavoidable as the size of the computation increases. Thermally activated anyons can corrupt the encoded
data by braiding or fusing with the computational anyons.

In the present work, we generalize a fault-tolerant scheme introduced by Harrington for the toric-code to the setting of non-cyclic modular anyons. We prove that the quantum information encoded in the fusion space of a non-abelian anyon system can be preserved for arbitrarily long times with poly-log overhead. In particular, our model accounts for noise processes which lead to the creation of anyon pairs from the vacuum, anyon diffusion, anyon fusion as well as errors in topological charge measurements.
Related Arxiv #: arXiv:1607.02159