A nonreciprocal optical resonator with broken time-invariance for arbitrarily high time-bandwidth performance
Ivan Cardea, Davide Grassani, Simon J. Fabbri, Jeremy Upham, Robert W., Boyd, Hatice Altug, Sebastian A. Schulz, Kosmas L. Tsakmakidis,, Camille-Sophie Br\`es

TL;DR
This paper demonstrates an experimental nonreciprocal optical resonator that breaks the fundamental time-bandwidth limit by using a time-variant cavity, enabling ultrafast and long storage of waves with potential for new wave physics applications.
Contribution
It provides the first experimental realization of a nonreciprocal cavity that overcomes the traditional time-bandwidth limit by breaking time invariance, with a simple fiber-optic setup.
Findings
Achieved a 30-fold increase in time-bandwidth product.
Demonstrated on-demand wave storage and release.
Validated results with numerical simulations.
Abstract
Most present-day resonant systems, throughout physics and engineering, are characterized by a strict time-reversal symmetry between the rates of energy coupled in and out of the system, which leads to a trade-off between how long a wave can be stored in the system and the system bandwidth. Any attempt to reduce the losses of the resonant system, and hence store a (mechanical, acoustic, electronic, optical, atomic, or of any other nature) wave for more time, will inevitably also reduce the bandwidth of the system. Until recently, this time-bandwidth limit has been considered fundamental, arising from basic Fourier reciprocity. A recent theory suggested that it might in fact be overcome by breaking Lorentz reciprocity in the resonant system, reinvigorated a debate about whether (or not) this was indeed the case. Here, we report an experimental realization of a cavity where, inducing…
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Taxonomy
TopicsPhotonic and Optical Devices · Mechanical and Optical Resonators · Gyrotron and Vacuum Electronics Research
