Breaking Lorentz reciprocity to overcome the time-bandwidth limit in physics and engineering

A century-old tenet in physics and engineering asserts that any type of system, having bandwidth Δω, can interact with a wave over only a constrained time period Δt inversely proportional to the bandwidth (Δt·Δω ~ 2π). This law severely limits the generic capabilities of all types of resonant and wa...

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Published inScience (American Association for the Advancement of Science) Vol. 356; no. 6344; pp. 1260 - 1264
Main Authors Tsakmakidis, K. L., Shen, L., Schulz, S. A., Zheng, X., Upham, J., Deng, X., Altug, H., Vakakis, A. F., Boyd, R. W.
Format Journal Article
LanguageEnglish
Published United States American Association for the Advancement of Science 23.06.2017
The American Association for the Advancement of Science
Subjects
Acoustics
Asymmetry
Bandwidth
Bandwidths
Continuum mechanics
Devices
Engineering
Narrowband
Opto-mechanics
Photonics
Physics
Q devices
Quantum electrodynamics
Reciprocity
Semiconductors
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Summary:A century-old tenet in physics and engineering asserts that any type of system, having bandwidth Δω, can interact with a wave over only a constrained time period Δt inversely proportional to the bandwidth (Δt·Δω ~ 2π). This law severely limits the generic capabilities of all types of resonant and wave-guiding systems in photonics, cavity quantum electrodynamics and optomechanics, acoustics, continuum mechanics, and atomic and optical physics but is thought to be completely fundamental, arising from basic Fourier reciprocity. We propose that this “fundamental” limit can be overcome in systems where Lorentz reciprocity is broken. As a system becomes more asymmetric in its transport properties, the degree to which the limit can be surpassed becomes greater. By way of example, we theoretically demonstrate how, in an astutely designed magnetized semiconductor heterostructure, the above limit can be exceeded by orders of magnitude by using realistic material parameters. Our findings revise prevailing paradigms for linear, time-invariant resonant systems, challenging the doctrine that high-quality resonances must invariably be narrowband and providing the possibility of developing devices with unprecedentedly high time-bandwidth performance.
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ISSN:0036-8075
1095-9203
DOI:10.1126/science.aam6662