1. Integrated optical multi-ion quantum logic
- Author
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Mehta, Karan K., Zhang, Chi, Malinowski, Maciej, Nguyen, Thanh-Long, Stadler, Martin, and Home, Jonathan P.
- Subjects
Ions -- Control ,Integrated optics -- Analysis ,Quantum computing -- Analysis ,Environmental issues ,Science and technology ,Zoology and wildlife conservation - Abstract
Practical and useful quantum information processing requires substantial improvements with respect to current systems, both in the error rates of basic operations and in scale. The fundamental qualities of individual trapped-ion.sup.1 qubits are promising for long-term systems.sup.2, but the optics involved in their precise control are a barrier to scaling.sup.3. Planar-fabricated optics integrated within ion-trap devices can make such systems simultaneously more robust and parallelizable, as suggested by previous work with single ions.sup.4. Here we use scalable optics co-fabricated with a surface-electrode ion trap to achieve high-fidelity multi-ion quantum logic gates, which are often the limiting elements in building up the precise, large-scale entanglement that is essential to quantum computation. Light is efficiently delivered to a trap chip in a cryogenic environment via direct fibre coupling on multiple channels, eliminating the need for beam alignment into vacuum systems and cryostats and lending robustness to vibrations and beam-pointing drifts. This allows us to perform ground-state laser cooling of ion motion and to implement gates generating two-ion entangled states with fidelities greater than 99.3(2) per cent. This work demonstrates hardware that reduces noise and drifts in sensitive quantum logic, and simultaneously offers a route to practical parallelization for high-fidelity quantum processors.sup.5. Similar devices may also find applications in atom- and ion-based quantum sensing and timekeeping.sup.6. Scalable optics co-fabricated with a cryogenic surface-electrode ion trap are used to drive high-fidelity multi-ion quantum logic gates, demonstrating a route to simultaneously scale and reduce errors in quantum processors., Author(s): Karan K. Mehta [sup.1] , Chi Zhang [sup.1] , Maciej Malinowski [sup.1] , Thanh-Long Nguyen [sup.1] , Martin Stadler [sup.1] , Jonathan P. Home [sup.1] Author Affiliations: (1) Department [...]
- Published
- 2020
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