Experimental Demonstration of Logical Magic State Distillation

• URL: http://arxiv.org/abs/2412.15165v1
• Date: Thu, 19 Dec 2024 18:38:46 GMT
• Title: Experimental Demonstration of Logical Magic State Distillation
• Authors: Pedro Sales Rodriguez, John M. Robinson, Paul Niklas Jepsen, Zhiyang He, Casey Duckering, Chen Zhao, Kai-Hsin Wu, Joseph Campo, Kevin Bagnall, Minho Kwon, Thomas Karolyshyn, Phillip Weinberg, Madelyn Cain, Simon J. Evered, Alexandra A. Geim, Marcin Kalinowski, Sophie H. Li, Tom Manovitz, Jesse Amato-Grill, James I. Basham, Liane Bernstein, Boris Braverman, Alexei Bylinskii, Adam Choukri, Robert DeAngelo, Fang Fang, Connor Fieweger, Paige Frederick, David Haines, Majd Hamdan, Julian Hammett, Ning Hsu, Ming-Guang Hu, Florian Huber, Ningyuan Jia, Dhruv Kedar, Milan Kornjača, Fangli Liu, John Long, Jonathan Lopatin, Pedro L. S. Lopes, Xiu-Zhe Luo, Tommaso Macrì, Ognjen Marković, Luis A. Martínez-Martínez, Xianmei Meng, Stefan Ostermann, Evgeny Ostroumov, David Paquette, Zexuan Qiang, Vadim Shofman, Anshuman Singh, Manuj Singh, Nandan Sinha, Henry Thoreen, Noel Wan, Yiping Wang, Daniel Waxman-Lenz, Tak Wong, Jonathan Wurtz, Andrii Zhdanov, Laurent Zheng, Markus Greiner, Alexander Keesling, Nathan Gemelke, Vladan Vuletić, Takuya Kitagawa, Sheng-Tao Wang, Dolev Bluvstein, Mikhail D. Lukin, Alexander Lukin, Hengyun Zhou, Sergio H. Cantú,
• Abstract summary: We present the experimental realization of magic state distillation with logical qubits on a neutral-atom quantum computer. Our approach makes use of a dynamically reconfigurable architecture to encode and perform quantum operations on many logical qubits in parallel.
• Score: 62.77974948443222
• License:
• Abstract: Realizing universal fault-tolerant quantum computation is a key goal in quantum information science. By encoding quantum information into logical qubits utilizing quantum error correcting codes, physical errors can be detected and corrected, enabling substantial reduction in logical error rates. However, the set of logical operations that can be easily implemented on such encoded qubits is often constrained, necessitating the use of special resource states known as 'magic states' to implement universal, classically hard circuits. A key method to prepare high-fidelity magic states is to perform 'distillation', creating them from multiple lower fidelity inputs. Here we present the experimental realization of magic state distillation with logical qubits on a neutral-atom quantum computer. Our approach makes use of a dynamically reconfigurable architecture to encode and perform quantum operations on many logical qubits in parallel. We demonstrate the distillation of magic states encoded in d=3 and d=5 color codes, observing improvements of the logical fidelity of the output magic states compared to the input logical magic states. These experiments demonstrate a key building block of universal fault-tolerant quantum computation, and represent an important step towards large-scale logical quantum processors.

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