Voltage-controlled extraordinary optical transmission in the visible
regime
- URL: http://arxiv.org/abs/2311.02949v2
- Date: Thu, 7 Mar 2024 17:05:12 GMT
- Title: Voltage-controlled extraordinary optical transmission in the visible
regime
- Authors: Hira Asif, Alpan Bek, Mehmet Emre Tasgin, Ramazan Sahin
- Abstract summary: Operation bandwidth of a plasmonic device cannot be generally tuned once it is manufactured.
We demonstrate the electrical control of such a device for extraordinary optical transmission(EOT) in the visible regime.
- Score: 2.765106384328772
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Control of components in integrated photonic circuits is crucial in achieving
programmable devices. Operation bandwidth of a plasmonic device cannot be
generally tuned once it is manufactured, especially in the visible regime.
Here, we demonstrate the electrical control of such a device for extraordinary
optical transmission~(EOT) in the visible regime. (i) Operation frequency of
the EOT device can be tuned via a bias voltage applied through nanowires. (ii)
Or, at a given frequency, the EOT signal (normalized to the incident field) can
be tuned continuously, e.g., between $10^{-4}$ and $0.4$. This corresponds to a
3-orders of magnitude modulation depth. We utilize Fano resonances induced by a
quantum emitter~(QE) that is embedded into the nanoholes. The external
bias-voltage tunes QE's resonance. We also discuss the lifetime extensions of
surface plasmon polaritons as a response to an ultra-short optical pulse. Our
proposed method provides the active electronic control of EOT signal which
makes it a feasible and compact element in integrated photonic circuits, for
bio-sensing, high resolution imaging, and molecular spectroscopy applications.
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