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Autori principali: Bock, Christoph L., Hernández, J. C. Rivera, Lingua, Fabio, Haviland, David B.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2501.09453
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author Bock, Christoph L.
Hernández, J. C. Rivera
Lingua, Fabio
Haviland, David B.
author_facet Bock, Christoph L.
Hernández, J. C. Rivera
Lingua, Fabio
Haviland, David B.
contents We investigate nonreciprocal scattering within the modes of a microwave frequency comb. Adjusting the pump frequencies, amplitudes, and phases of a Josephson parametric oscillator, we control constructive interference for the $m \longrightarrow \ell$ scattering processes, while concurrently achieving destructive interference for the inverse process $\ell \longrightarrow m$. We outline the methodology for realizing nonreciprocity in the context of two-mode isolation and a three-mode circulation, which we extend to multiple modes. We find good agreement between the experiments and a linearized theoretical model. Nonreciprocal scattering expands the toolset for parametric control, with the potential to engineer alternative quantum correlations.
format Preprint
id arxiv_https___arxiv_org_abs_2501_09453
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Non-reciprocal scattering in a microwave frequency comb
Bock, Christoph L.
Hernández, J. C. Rivera
Lingua, Fabio
Haviland, David B.
Quantum Physics
Applied Physics
We investigate nonreciprocal scattering within the modes of a microwave frequency comb. Adjusting the pump frequencies, amplitudes, and phases of a Josephson parametric oscillator, we control constructive interference for the $m \longrightarrow \ell$ scattering processes, while concurrently achieving destructive interference for the inverse process $\ell \longrightarrow m$. We outline the methodology for realizing nonreciprocity in the context of two-mode isolation and a three-mode circulation, which we extend to multiple modes. We find good agreement between the experiments and a linearized theoretical model. Nonreciprocal scattering expands the toolset for parametric control, with the potential to engineer alternative quantum correlations.
title Non-reciprocal scattering in a microwave frequency comb
topic Quantum Physics
Applied Physics
url https://arxiv.org/abs/2501.09453