Application of a Resource Theory for Magic States to Fault-Tolerant Quantum Computing

Mark Howard; Earl Campbell

doi:10.1103/PhysRevLett.118.090501

Application of a Resource Theory for Magic States to Fault-Tolerant Quantum Computing

Mark Howard, Earl Campbell

University of Sheffield

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

242 Citations (Scopus)

Abstract

Motivated by their necessity for most fault-tolerant quantum computation schemes, we formulate a resource theory for magic states. First, we show that robustness of magic is a well-behaved magic monotone that operationally quantifies the classical simulation overhead for a Gottesman-Knill-type scheme using ancillary magic states. Our framework subsequently finds immediate application in the task of synthesizing non-Clifford gates using magic states. When magic states are interspersed with Clifford gates, Pauli measurements, and stabilizer ancillas - the most general synthesis scenario - then the class of synthesizable unitaries is hard to characterize. Our techniques can place nontrivial lower bounds on the number of magic states required for implementing a given target unitary. Guided by these results, we have found new and optimal examples of such synthesis.

Original language	English
Article number	090501
Journal	Physical Review Letters
Volume	118
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevLett.118.090501
Publication status	Published - 3 Mar 2017
Externally published	Yes

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AB - Motivated by their necessity for most fault-tolerant quantum computation schemes, we formulate a resource theory for magic states. First, we show that robustness of magic is a well-behaved magic monotone that operationally quantifies the classical simulation overhead for a Gottesman-Knill-type scheme using ancillary magic states. Our framework subsequently finds immediate application in the task of synthesizing non-Clifford gates using magic states. When magic states are interspersed with Clifford gates, Pauli measurements, and stabilizer ancillas - the most general synthesis scenario - then the class of synthesizable unitaries is hard to characterize. Our techniques can place nontrivial lower bounds on the number of magic states required for implementing a given target unitary. Guided by these results, we have found new and optimal examples of such synthesis.

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Application of a Resource Theory for Magic States to Fault-Tolerant Quantum Computing

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