TY - JOUR T1 - Fault-Tolerant Operation of a Quantum Error-Correction Code Y1 - 2020 A1 - Laird Egan A1 - Dripto M. Debroy A1 - Crystal Noel A1 - Andrew Risinger A1 - Daiwei Zhu A1 - Debopriyo Biswas A1 - Michael Newman A1 - Muyuan Li A1 - Kenneth R. Brown A1 - Marko Cetina A1 - Christopher Monroe AB -

Quantum error correction protects fragile quantum information by encoding it in a larger quantum system whose extra degrees of freedom enable the detection and correction of errors. An encoded logical qubit thus carries increased complexity compared to a bare physical qubit. Fault-tolerant protocols contain the spread of errors and are essential for realizing error suppression with an error-corrected logical qubit. Here we experimentally demonstrate fault-tolerant preparation, rotation, error syndrome extraction, and measurement on a logical qubit encoded in the 9-qubit Bacon-Shor code. For the logical qubit, we measure an average fault-tolerant preparation and measurement error of 0.6% and a transversal Clifford gate with an error of 0.3% after error correction. The result is an encoded logical qubit whose logical fidelity exceeds the fidelity of the entangling operations used to create it. We compare these operations with non-fault-tolerant protocols capable of generating arbitrary logical states, and observe the expected increase in error. We directly measure the four Bacon-Shor stabilizer generators and are able to detect single qubit Pauli errors. These results show that fault-tolerant quantum systems are currently capable of logical primitives with error rates lower than their constituent parts. With the future addition of intermediate measurements, the full power of scalable quantum error-correction can be achieved. 

UR - https://arxiv.org/abs/2009.11482 ER -