Issue 17, 2020

A broadband and low-power light-control-light effect in a fiber-optic nano-optomechanical system

Abstract

The coupling of the optical and mechanical degrees of freedom using optical force in nano-devices offers a novel mechanism to implement all-optical signal processing. However, the ultra-weak optical force requires a high pump optical power to realize all-optical processing. For such devices, it is still challenging to lower the pump power and simultaneously broaden the bandwidth of the signal light under processing. In this work, a simple and cost-effective optomechanical scheme was demonstrated that was capable of achieving a broadband (208 nm) and micro-Watt (∼624.13 μW) light-control-light effect driven by a relatively weak optical force (∼3 pN). In the scheme, a tapered nanofiber (TNF) was evanescently coupled with a substrate, allowing the pump light guided in the TNF to generate a strong transverse optical force for the light-control-light effect. Additionally, thanks to the low stiffness (5.44 fN nm−1) of the TNF, the light-control-light scheme also provided a simple method to measure the static weak optical force with a minimum detectable optical force down to 380.8 fN. The results establish TNF as a cost-effective scheme to break the limitation of the modulation wavelength bandwidth (MWB) at a low pump power and show that the TNF-optic optomechanical system can be well described as a harmonic oscillator.

Graphical abstract: A broadband and low-power light-control-light effect in a fiber-optic nano-optomechanical system

Article information

Article type
Paper
Submitted
30 Dec 2019
Accepted
30 Mar 2020
First published
30 Mar 2020

Nanoscale, 2020,12, 9800-9809

A broadband and low-power light-control-light effect in a fiber-optic nano-optomechanical system

Y. Zhang, W. Zhu, P. Fan, Y. He, L. Zhuo, Z. Che, D. Li, H. Zheng, L. Dong, J. Tang, W. Qiu, J. Zhang, Y. Zhong, J. Yu and Z. Chen, Nanoscale, 2020, 12, 9800 DOI: 10.1039/C9NR10953F

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