Multi-time quantum process tomography on a superconducting qubit
ORAL
Abstract
The characterisation of noise is a critical requirement for advancing quantum technologies. Noise is present in all current quantum devices as they interact with their environment; for many devices, this includes non-Markovian noise due to temporal correlations across a multi-time process. While most current techniques assume Markovian noise, this assumption fails in realistic quantum devices, and non-Markovian noise has been reported in state-of-the-art quantum computing devices (such as IBM and Google) [1,2].
Past general approaches to capture non-Markovian noise only provide access to two times of a quantum process through dynamical maps. Recently, a formalism was developed that constructs a process matrix [3,4], which encodes all multi-time correlations and investigates its nature (classical or quantum) and amount [5].
Here, we present the first implementation of full process tomography of a multi-time quantum process on a superconducting qubit and obtain measures of non-Markovianity. We implement mid-circuit measurements and overcome the need for a feed-forward mechanism with a post-processing trick. We use in-house and cloud-based quantum processors to measure general and quantum non-Markovian noise and build a theoretical model to compare our findings. Our work offers a robust method for fully characterising non-Markovian noise, significantly advancing both our theoretical understanding and the development of noise mitigation techniques.
[1] J. Morris, F. A. Pollock, and K. Modi, Open Systems & Information Dynamics 29, 10.1142/S123016122250007X (2022).
[2] M. McEwen et al., Nature Communications 12, 10.1038/s41467-021-21982-y (2021).
[3] O. Oreshkov, F. Costa, and Č. Brukner, Nat. Commun. 3, 1092 (2012).
[4] O. Oreshkov and C. Giarmatzi, New J. Phys. 18, 093020 (2016).
[5] C. Giarmatzi and F. Costa, Quantum 5, 440 (2021).
Past general approaches to capture non-Markovian noise only provide access to two times of a quantum process through dynamical maps. Recently, a formalism was developed that constructs a process matrix [3,4], which encodes all multi-time correlations and investigates its nature (classical or quantum) and amount [5].
Here, we present the first implementation of full process tomography of a multi-time quantum process on a superconducting qubit and obtain measures of non-Markovianity. We implement mid-circuit measurements and overcome the need for a feed-forward mechanism with a post-processing trick. We use in-house and cloud-based quantum processors to measure general and quantum non-Markovian noise and build a theoretical model to compare our findings. Our work offers a robust method for fully characterising non-Markovian noise, significantly advancing both our theoretical understanding and the development of noise mitigation techniques.
[1] J. Morris, F. A. Pollock, and K. Modi, Open Systems & Information Dynamics 29, 10.1142/S123016122250007X (2022).
[2] M. McEwen et al., Nature Communications 12, 10.1038/s41467-021-21982-y (2021).
[3] O. Oreshkov, F. Costa, and Č. Brukner, Nat. Commun. 3, 1092 (2012).
[4] O. Oreshkov and C. Giarmatzi, New J. Phys. 18, 093020 (2016).
[5] C. Giarmatzi and F. Costa, Quantum 5, 440 (2021).
*CG acknowledges funding from the Sydney Quantum Academy Fellowship and the UTS Chancellor’s Research Fellowship. FC was supported by the Wallenberg Initiative on Networks and Quantum Information (WINQ). This work was supported by the Australian Research Council (ARC) Centre of Excellence for Quantum Engineered Systems grant (CE 170100009). Nordita is supported in part by NordForsk.
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Publication: https://doi.org/10.48550/arXiv.2308.00750
Presenters
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Christina Giarmatzi
- Macquarie University