Light interaction with a space-time-modulated Josephson junction array and application to angular-frequency beam multiplexing
Light interaction with a space-time-modulated Josephson junction array and application to angular-frequency beam multiplexing
Josephson junctions, as pivotal components of modern technologies such as superconducting quantum computing, owe their prominence to their unique nonlinear properties at low temperatures. Despite their extensive use in static configurations, the study of dynamic Josephson junctions, particularly under space-time modulation, remains largely unexplored. This study investigates the interaction and transmission of electromagnetic waves through arrays of space-time-modulated Josephson junctions. A comprehensive mathematical framework is presented to model the propagation of electric and magnetic fields within and beyond these structures. We demonstrate how such dynamic arrays enable groundbreaking four-dimensional light manipulation, achieving angular-frequency beam multiplexing through a seamless integration of frequency conversion and beam-splitting functionalities. These advancements open new horizons for electromagnetic field engineering, with far-reaching implications for superconducting quantum technologies, next-generation wireless communications, biomedical sensing, and radar systems.
cond-mat.supr-con, physics.optics
Taravati, Sajjad
0026f25d-c919-4273-b956-8fe9795b31ce
3 January 2025
Taravati, Sajjad
0026f25d-c919-4273-b956-8fe9795b31ce
[Unknown type: UNSPECIFIED]
Abstract
Josephson junctions, as pivotal components of modern technologies such as superconducting quantum computing, owe their prominence to their unique nonlinear properties at low temperatures. Despite their extensive use in static configurations, the study of dynamic Josephson junctions, particularly under space-time modulation, remains largely unexplored. This study investigates the interaction and transmission of electromagnetic waves through arrays of space-time-modulated Josephson junctions. A comprehensive mathematical framework is presented to model the propagation of electric and magnetic fields within and beyond these structures. We demonstrate how such dynamic arrays enable groundbreaking four-dimensional light manipulation, achieving angular-frequency beam multiplexing through a seamless integration of frequency conversion and beam-splitting functionalities. These advancements open new horizons for electromagnetic field engineering, with far-reaching implications for superconducting quantum technologies, next-generation wireless communications, biomedical sensing, and radar systems.
Text
2501.01842v1
- Author's Original
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Published date: 3 January 2025
Keywords:
cond-mat.supr-con, physics.optics
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Local EPrints ID: 498653
URI: http://eprints.soton.ac.uk/id/eprint/498653
PURE UUID: 0c247ea4-7e10-48e8-b978-951f48c6d87c
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Date deposited: 25 Feb 2025 17:31
Last modified: 26 Feb 2025 03:12
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Author:
Sajjad Taravati
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