Qudit-native measurement protocol for dynamical correlations using Hadamard tests

• URL: http://arxiv.org/abs/2407.03421v1
• Date: Wed, 3 Jul 2024 18:01:29 GMT
• Title: Qudit-native measurement protocol for dynamical correlations using Hadamard tests
• Authors: Pavel P. Popov, Kevin T. Geier, Valentin Kasper, Maciej Lewenstein, Philipp Hauke,
• Abstract summary: Dynamical correlations reveal important out-of-equilibrium properties of the underlying quantum many-body system. We propose a modified protocol to overcome this limitation by decomposing qudit observables into unitary operations. Our scheme can readily be implemented on various platforms and offers a wide range of applications.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Dynamical correlations reveal important out-of-equilibrium properties of the underlying quantum many-body system, yet they are notoriously difficult to measure in experiments. While measurement protocols for dynamical correlations based on Hadamard tests for qubit quantum devices exist, they do not straightforwardly extend to qudits. Here, we propose a modified protocol to overcome this limitation by decomposing qudit observables into unitary operations that can be implemented and probed in a quantum circuit. We benchmark our algorithm numerically at the example of quench dynamics in a spin-1 XXZ chain with finite shot noise and demonstrate advantages in terms of signal-to-noise ratio over established protocols based on linear response. Our scheme can readily be implemented on various platforms and offers a wide range of applications like variational quantum optimization or probing thermalization in many-body systems.

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