OMG Architecture Implementation in <sup>171</sup>Yb<sup>+</sup> Ion Chains
ORAL
Abstract
As quantum computing platforms continue to scale up, efficient mid-circuit partial measurements become necessary to support extended, intricate, and fault-tolerant circuits. The existing mid-circuit measurement protocols implemented in trapped-ion quantum computing systems, however, rely on ion chain splitting, shuttling, and merging, which introduces additional risks of ion chain heating. OMG architecture enables a different approach to mid-circuit measurement that does not involve ion chain manipulation.
In this work, we investigate the OMG architecture implementation in a long 171Yb+ ion chain. We utilize shelving to 2F7/2 metastable state via 2S1/2 → 2D5/2 and 2D5/2 → 2F7/2 transitions to protect qubits while performing dissipative processes on the target qubits in their ground 2S1/2 state. We discuss approaches to selective mid-circuit measurement in long Yb ion chains using OMG architecture.
In this work, we investigate the OMG architecture implementation in a long 171Yb+ ion chain. We utilize shelving to 2F7/2 metastable state via 2S1/2 → 2D5/2 and 2D5/2 → 2F7/2 transitions to protect qubits while performing dissipative processes on the target qubits in their ground 2S1/2 state. We discuss approaches to selective mid-circuit measurement in long Yb ion chains using OMG architecture.
*This work is supported by the NSF STAQ Program, the DOE QSA Program, the AFOSR MURI on Quantum Dissipation Engineering and the AFOSR MURI on Certification of Quantum Computers.
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Presenters
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Keqin Yan
- Duke University