All-optical control of microfiber resonator by graphene's photothermal effect

Yadong Wang; Xuetao Gan; Chenyang Zhao; Liang Fang; Dong Mao; Yiping Xu; Fanlu Zhang; Teli Xi; Liyong Ren; Jianlin Zhao

doi:10.1063/1.4947577

All-optical control of microfiber resonator by graphene's photothermal effect

Yadong Wang, Xuetao Gan, Chenyang Zhao, Liang Fang, Dong Mao, Yiping Xu, Fanlu Zhang, Teli Xi, Liyong Ren, Jianlin Zhao

Research output: Contribution to journal › Article › peer-review

82 Scopus citations

Abstract

We demonstrate an efficient all-optical control of microfiber resonator assisted by graphene's photothermal effect. Wrapping graphene onto a microfiber resonator, the light-graphene interaction can be strongly enhanced via the resonantly circulating light, which enables a significant modulation of the resonance with a resonant wavelength shift rate of 71 pm/mW when pumped by a 1540 nm laser. The optically controlled resonator enables the implementation of low threshold optical bistability and switching with an extinction ratio exceeding 13 dB. The thin and compact structure promises a fast response speed of the control, with a rise (fall) time of 294.7 μs (212.2 μs) following the 10%-90% rule. The proposed device, with the advantages of compact structure, all-optical control, and low power acquirement, offers great potential in the miniaturization of active in-fiber photonic devices.

Original language	English
Article number	171905
Journal	Applied Physics Letters
Volume	108
Issue number	17
DOIs	https://doi.org/10.1063/1.4947577
State	Published - 25 Apr 2016

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abstract = "We demonstrate an efficient all-optical control of microfiber resonator assisted by graphene's photothermal effect. Wrapping graphene onto a microfiber resonator, the light-graphene interaction can be strongly enhanced via the resonantly circulating light, which enables a significant modulation of the resonance with a resonant wavelength shift rate of 71 pm/mW when pumped by a 1540 nm laser. The optically controlled resonator enables the implementation of low threshold optical bistability and switching with an extinction ratio exceeding 13 dB. The thin and compact structure promises a fast response speed of the control, with a rise (fall) time of 294.7 μs (212.2 μs) following the 10%-90% rule. The proposed device, with the advantages of compact structure, all-optical control, and low power acquirement, offers great potential in the miniaturization of active in-fiber photonic devices.",

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AU - Wang, Yadong

AU - Gan, Xuetao

AU - Zhao, Chenyang

AU - Fang, Liang

AU - Mao, Dong

AU - Xu, Yiping

AU - Zhang, Fanlu

AU - Xi, Teli

AU - Ren, Liyong

AU - Zhao, Jianlin

PY - 2016/4/25

Y1 - 2016/4/25

N2 - We demonstrate an efficient all-optical control of microfiber resonator assisted by graphene's photothermal effect. Wrapping graphene onto a microfiber resonator, the light-graphene interaction can be strongly enhanced via the resonantly circulating light, which enables a significant modulation of the resonance with a resonant wavelength shift rate of 71 pm/mW when pumped by a 1540 nm laser. The optically controlled resonator enables the implementation of low threshold optical bistability and switching with an extinction ratio exceeding 13 dB. The thin and compact structure promises a fast response speed of the control, with a rise (fall) time of 294.7 μs (212.2 μs) following the 10%-90% rule. The proposed device, with the advantages of compact structure, all-optical control, and low power acquirement, offers great potential in the miniaturization of active in-fiber photonic devices.

AB - We demonstrate an efficient all-optical control of microfiber resonator assisted by graphene's photothermal effect. Wrapping graphene onto a microfiber resonator, the light-graphene interaction can be strongly enhanced via the resonantly circulating light, which enables a significant modulation of the resonance with a resonant wavelength shift rate of 71 pm/mW when pumped by a 1540 nm laser. The optically controlled resonator enables the implementation of low threshold optical bistability and switching with an extinction ratio exceeding 13 dB. The thin and compact structure promises a fast response speed of the control, with a rise (fall) time of 294.7 μs (212.2 μs) following the 10%-90% rule. The proposed device, with the advantages of compact structure, all-optical control, and low power acquirement, offers great potential in the miniaturization of active in-fiber photonic devices.

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All-optical control of microfiber resonator by graphene's photothermal effect

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