Demonstration of universal control between non-interacting qubits using the Quantum Zeno effect

E. Blumenthal; C. Mor; A. A. Diringer; L. S. Martin; P. Lewalle; D. Burgarth; K. B. Whaley; S. Hacohen-Gourgy

doi:10.1038/s41534-022-00594-4

Demonstration of universal control between non-interacting qubits using the Quantum Zeno effect

E. Blumenthal, C. Mor, A. A. Diringer, L. S. Martin, P. Lewalle, D. Burgarth, K. B. Whaley, S. Hacohen-Gourgy

Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

The Zeno effect occurs in quantum systems when a very strong measurement is applied, which can alter the dynamics in non-trivial ways. Despite being dissipative, the dynamics stay coherent within any degenerate subspaces of the measurement. Here we show that such a measurement can turn a single-qubit operation into a two- or multi-qubit entangling gate, even in a non-interacting system. We demonstrate this gate between two effectively non-interacting transmon qubits. Our Zeno gate works by imparting a geometric phase on the system, conditioned on it lying within a particular non-local subspace. These results show how universality can be generated not only by coherent interactions as is typically employed in quantum information platforms, but also by Zeno measurements.

Original language	English
Article number	88
Journal	npj Quantum Information
Volume	8
Issue number	1
DOIs	https://doi.org/10.1038/s41534-022-00594-4
State	Published - 25 Jul 2022

All Science Journal Classification (ASJC) codes

Computer Science (miscellaneous)
Statistical and Nonlinear Physics
Computer Networks and Communications
Computational Theory and Mathematics

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10.1038/s41534-022-00594-4

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abstract = "The Zeno effect occurs in quantum systems when a very strong measurement is applied, which can alter the dynamics in non-trivial ways. Despite being dissipative, the dynamics stay coherent within any degenerate subspaces of the measurement. Here we show that such a measurement can turn a single-qubit operation into a two- or multi-qubit entangling gate, even in a non-interacting system. We demonstrate this gate between two effectively non-interacting transmon qubits. Our Zeno gate works by imparting a geometric phase on the system, conditioned on it lying within a particular non-local subspace. These results show how universality can be generated not only by coherent interactions as is typically employed in quantum information platforms, but also by Zeno measurements.",

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AU - Blumenthal, E.

AU - Mor, C.

AU - Diringer, A. A.

AU - Martin, L. S.

AU - Lewalle, P.

AU - Burgarth, D.

AU - Whaley, K. B.

AU - Hacohen-Gourgy, S.

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AB - The Zeno effect occurs in quantum systems when a very strong measurement is applied, which can alter the dynamics in non-trivial ways. Despite being dissipative, the dynamics stay coherent within any degenerate subspaces of the measurement. Here we show that such a measurement can turn a single-qubit operation into a two- or multi-qubit entangling gate, even in a non-interacting system. We demonstrate this gate between two effectively non-interacting transmon qubits. Our Zeno gate works by imparting a geometric phase on the system, conditioned on it lying within a particular non-local subspace. These results show how universality can be generated not only by coherent interactions as is typically employed in quantum information platforms, but also by Zeno measurements.

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Demonstration of universal control between non-interacting qubits using the Quantum Zeno effect

Abstract

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