(a) Scanning electron microscope (SEM) image of a channel waveguide (WG) with a lithographically defined symmetric meta-unit on SOI substrate. (b) Scanning electron microscope (SEM) image of a channel waveguide (WG) with a lithographically defined rectangular-shaped symmetric Mie-scatterer on SOI substrate (top). Design parameter space for such Mie scatterer (bottom). (c) Optical impedance matching of the complex reflection coefficient to obtain zero reflection at exceptional point (EP).
Newswise — Non-Hermitian systems with their spectral degeneracies known as exceptional points (EPs) have been explored for lasing, controlling light transport, and enhancing a sensor’s response. A ring resonator can be brought to an EP by controlling the coupling between its frequency degenerate clockwise and counterclockwise traveling modes. This has been typically achieved by introducing two or more nano-tips into the resonator’s mode volume. While this method provides a route to study EP physics, the basic understanding of how the nano-tips’ shape and size symmetry impact the system’s non-Hermicity is missing, along with additional loss from both in-plane and out-of-plane scattering. The limited resonance stability poses a challenge for leveraging EP effects for switches or modulators, which requires stable cavity resonance and fixed laser-cavity detuning.
In a new paper published in eLight, a team of scientists, led by Professor Tingyi Gu from the Department of Electrical and Computer Engineering, University of Delaware, USA, and co-workers have developed lithographically defined asymmetric and symmetric Mie-scatterers. It enables subwavelength control of wave transmission and reflections without deflecting to additional radiation channels. They show that those pre-defined meta-units can bring the system to an EP without post-tuning and enable chiral light transport within the resonator. Counterintuitively, a geometric defect, named meta-unit, results in an enhanced quality factor measured on the transmission port by coherently suppressing the backscattering from surface roughness. The proposed device platform enables pre-defined chiral light propagation and backscattering-free resonances, needed for various applications such as frequency combs, solitons, sensing, and other nonlinear optical processes such as photon blockade, and regenerative oscillators.
These scientists emphasize the significance of their work:
“Our work not only opens a new direction for chiral silicon photonics but is also significant for the following four reasons.
First, it reveals the critical role of spatial asymmetry of the nano-tip and Mie scatterers for bringing the system towards EP. Second, the scatter geometry-controlled pathway of driving the non-Hermitian system towards and away from an EP is illustrated in detail.
Third, our system is mechanically stable. It allows reliable comparison between transmission and reflection spectra for the perturbed micro-resonator, which reveals the nano-tip/scatter’s contribution to the diagonal terms. This is in contrast to the conventional way of achieving EP with two nano-tips. Fourth, enhancement of the empirical quality factor extracted from the transmission spectra is demonstrated for the first time.”
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References
DOI
Original Source URL
https://doi.org/10.1186/s43593-023-00043-5
Funding information
This work is supported by the Defense Advanced Research Projects Agency (N660012114034) and the Air Force Office of Scientific Research (AFOSR) Multi-University Research Initiative (FA9550-21-1-0202, FA9550-18-1-0235 and FA9550-18-1-0300).
About eLight
eLight will primarily publish the finest manuscripts, broadly covering all sub-fields of optics, photonics, and electromagnetics. In particular, we focus on those emerging topics and cross-disciplinary research related to optics.
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