Your search keyword '"Vetter PJ"' showing total 2 results

1. Gate-set evaluation metrics for closed-loop optimal control on nitrogen-vacancy center ensembles in diamond.

Author

Vetter PJ, Reisser T, Hirsch MG, Calarco T, Motzoi F, Jelezko F, and Müller MM

Abstract

A recurring challenge in quantum science and technology is the precise control of their underlying dynamics that lead to the desired quantum operations, often described by a set of quantum gates. These gates can be subject to application-specific errors, leading to a dependence of their controls on the chosen circuit, the quality measure and the gate-set itself. A natural solution would be to apply quantum optimal control in an application-oriented fashion. In turn, this requires the definition of a meaningful measure of the contextual gate-set performance. Therefore, we explore and compare the applicability of quantum process tomography, linear inversion gate-set tomography, randomized linear gate-set tomography, and randomized benchmarking as measures for closed-loop quantum optimal control experiments, using a macroscopic ensemble of nitrogen-vacancy centers in diamond as a test-bed. Our work demonstrates the relative trade-offs between those measures and how to significantly enhance the gate-set performance, leading to an improvement across all investigated methods., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2024.)

Published

2024

2. Controllable Non-Markovianity for a Spin Qubit in Diamond.

Author

Haase JF, Vetter PJ, Unden T, Smirne A, Rosskopf J, Naydenov B, Stacey A, Jelezko F, Plenio MB, and Huelga SF

Abstract

We present a flexible scheme to realize non-Markovian dynamics of an electronic spin qubit, using a nitrogen-vacancy center in diamond where the inherent nitrogen spin serves as a regulator of the dynamics. By changing the population of the nitrogen spin, we show that we can smoothly tune the non-Markovianity of the electron spin's dynamics. Furthermore, we examine the decoherence dynamics induced by the spin bath to exclude other sources of non-Markovianity. The amount of collected measurement data is kept at a minimum by employing Bayesian data analysis. This allows for a precise quantification of the parameters involved in the description of the dynamics and a prediction of so far unobserved data points.

Published

2018