Abstract
AbstractQuantum systems evolve in time in one of two ways: through the Schrödinger equation or wavefunction collapse. So far, deterministic control of quantum many-body systems in the lab has focused on the former, due to the probabilistic nature of measurements. This imposes serious limitations: preparing long-range entangled states, for example, requires extensive circuit depth if restricted to unitary dynamics. In this work, we use mid-circuit measurement and feed-forward to implement deterministic non-unitary dynamics on Quantinuum’s H1 programmable ion-trap quantum computer. Enabled by these capabilities, we demonstrate a constant-depth procedure for creating a toric code ground state in real-time. In addition to reaching high stabilizer fidelities, we create a non-Abelian defect whose presence is confirmed by transmuting anyons via braiding. This work clears the way towards creating complex topological orders in the lab and exploring deterministic non-unitary dynamics via measurement and feed-forward.
Publisher
Springer Science and Business Media LLC
Reference63 articles.
1. Dennis, E., Kitaev, A., Landahl, A. & Preskill, J. Topological quantum memory. J. Math. Phys. 43, 4452–4505 (2002).
2. Wen, X.-G. Quantum Field Theory of Many-Body Systems. Oxford Graduate Texts (Oxford University Press, Oxford, 2010).
3. Altman, E. et al. Quantum simulators: architectures and opportunities. PRX Quantum 2, 017003 (2021).
4. Kitaev, A. Y. Quantum measurements and the Abelian stabilizer problem (1995).
5. Lu, S., Bañuls, M. C. & Cirac, J. I. Algorithms for quantum simulation at finite energies. PRX Quantum 2, 020321 (2021).
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