High-Speed and On-Chip Optical Switch Based on a Graphene Microheater

Shoma Nakamura; Kota Sekiya; Shinichiro Matano; Yui Shimura; Yuuki Nakade; Kenta Nakagawa; Yasuaki Monnai; Hideyuki Maki

doi:10.1021/acsnano.1c09526

High-Speed and On-Chip Optical Switch Based on a Graphene Microheater

Shoma Nakamura, Kota Sekiya, Shinichiro Matano, Yui Shimura, Yuuki Nakade, Kenta Nakagawa, Yasuaki Monnai, Hideyuki Maki^*

^*Corresponding author for this work

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

Abstract

Graphene is a promising material for producing optical devices because of its optical, electronic, thermal, and mechanical properties. Here, we demonstrated on-chip optical switches equipped with a graphene heater, which exhibited high modulation speed and efficiency. We designed the optimal structure of the optical switch with an add/drop-type racetrack resonator and two output waveguides (the through and drop ports) by the electromagnetic field calculation. We fabricated the optical switch in which the graphene microheater was directly placed on the resonator and directly observed its operation utilizing a near-infrared camera. As observed from the transmission spectra, this device exhibited high wavelength tuning efficiency of 0.24 nm/mW and high heating efficiency of 7.66 K·μm³/mW. Further, we measured the real-time high-speed operation at 100 kHz and verified that the graphene-based optical switch achieved high-speed modulation with 10%-90% rise and fall response times, 1.2 and 3.6 μs, respectively, thus confirming that they are significantly faster than typical optical switches that are based on racetrack resonators and metal heaters with response times of ∼100 μs. These graphene-based optical switches on silicon chips with high efficiency and speed are expected to enable high-performance silicon photonics and integrated optoelectronic applications.

Original language	English
Pages (from-to)	2690-2698
Number of pages	9
Journal	ACS Nano
Volume	16
Issue number	2
DOIs	https://doi.org/10.1021/acsnano.1c09526
Publication status	Published - 2022 Feb 22
Externally published	Yes

Keywords

graphene
racetrack resonators
silicon photonics
silicon waveguide
thermo-optic switch

ASJC Scopus subject areas

Materials Science(all)
Engineering(all)
Physics and Astronomy(all)

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10.1021/acsnano.1c09526

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title = "High-Speed and On-Chip Optical Switch Based on a Graphene Microheater",

abstract = "Graphene is a promising material for producing optical devices because of its optical, electronic, thermal, and mechanical properties. Here, we demonstrated on-chip optical switches equipped with a graphene heater, which exhibited high modulation speed and efficiency. We designed the optimal structure of the optical switch with an add/drop-type racetrack resonator and two output waveguides (the through and drop ports) by the electromagnetic field calculation. We fabricated the optical switch in which the graphene microheater was directly placed on the resonator and directly observed its operation utilizing a near-infrared camera. As observed from the transmission spectra, this device exhibited high wavelength tuning efficiency of 0.24 nm/mW and high heating efficiency of 7.66 K·μm3/mW. Further, we measured the real-time high-speed operation at 100 kHz and verified that the graphene-based optical switch achieved high-speed modulation with 10%-90% rise and fall response times, 1.2 and 3.6 μs, respectively, thus confirming that they are significantly faster than typical optical switches that are based on racetrack resonators and metal heaters with response times of ∼100 μs. These graphene-based optical switches on silicon chips with high efficiency and speed are expected to enable high-performance silicon photonics and integrated optoelectronic applications.",

keywords = "graphene, racetrack resonators, silicon photonics, silicon waveguide, thermo-optic switch",

author = "Shoma Nakamura and Kota Sekiya and Shinichiro Matano and Yui Shimura and Yuuki Nakade and Kenta Nakagawa and Yasuaki Monnai and Hideyuki Maki",

note = "Funding Information: The authors thank D. Tsuya, E. Watanabe, H. Osato, M. Yoshida, S. Moriyama, and K. Komatsu in NIMS and H. Sumikura in NTT Basic Research Laboratories for technical support and discussions. This work was technically supported by Kanagawa Institute of Industrial Science and Technology (KISTEC), Core-to-Core program from JSPS, Spintronics Research Network of Japan, and NIMS Nanofabrication Platform in Nanotechnology Platform Project sponsored by the Ministry of Education, Culture, Sports, Science and Technology (MEXT), Japan. This work was partially financially supported by PRESTO (Grant Number JPMJPR152B) and A-STEP (Grant Number JPMJTR20R4) from JST and KAKENHI (Grant Numbers 16H04355, 23686055, 18K19025, and 20H02210). Publisher Copyright: {\textcopyright} 2022 American Chemical Society",

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doi = "10.1021/acsnano.1c09526",

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T1 - High-Speed and On-Chip Optical Switch Based on a Graphene Microheater

AU - Nakamura, Shoma

AU - Sekiya, Kota

AU - Matano, Shinichiro

AU - Shimura, Yui

AU - Nakade, Yuuki

AU - Nakagawa, Kenta

AU - Monnai, Yasuaki

AU - Maki, Hideyuki

N1 - Funding Information: The authors thank D. Tsuya, E. Watanabe, H. Osato, M. Yoshida, S. Moriyama, and K. Komatsu in NIMS and H. Sumikura in NTT Basic Research Laboratories for technical support and discussions. This work was technically supported by Kanagawa Institute of Industrial Science and Technology (KISTEC), Core-to-Core program from JSPS, Spintronics Research Network of Japan, and NIMS Nanofabrication Platform in Nanotechnology Platform Project sponsored by the Ministry of Education, Culture, Sports, Science and Technology (MEXT), Japan. This work was partially financially supported by PRESTO (Grant Number JPMJPR152B) and A-STEP (Grant Number JPMJTR20R4) from JST and KAKENHI (Grant Numbers 16H04355, 23686055, 18K19025, and 20H02210). Publisher Copyright: © 2022 American Chemical Society

PY - 2022/2/22

Y1 - 2022/2/22

N2 - Graphene is a promising material for producing optical devices because of its optical, electronic, thermal, and mechanical properties. Here, we demonstrated on-chip optical switches equipped with a graphene heater, which exhibited high modulation speed and efficiency. We designed the optimal structure of the optical switch with an add/drop-type racetrack resonator and two output waveguides (the through and drop ports) by the electromagnetic field calculation. We fabricated the optical switch in which the graphene microheater was directly placed on the resonator and directly observed its operation utilizing a near-infrared camera. As observed from the transmission spectra, this device exhibited high wavelength tuning efficiency of 0.24 nm/mW and high heating efficiency of 7.66 K·μm3/mW. Further, we measured the real-time high-speed operation at 100 kHz and verified that the graphene-based optical switch achieved high-speed modulation with 10%-90% rise and fall response times, 1.2 and 3.6 μs, respectively, thus confirming that they are significantly faster than typical optical switches that are based on racetrack resonators and metal heaters with response times of ∼100 μs. These graphene-based optical switches on silicon chips with high efficiency and speed are expected to enable high-performance silicon photonics and integrated optoelectronic applications.

AB - Graphene is a promising material for producing optical devices because of its optical, electronic, thermal, and mechanical properties. Here, we demonstrated on-chip optical switches equipped with a graphene heater, which exhibited high modulation speed and efficiency. We designed the optimal structure of the optical switch with an add/drop-type racetrack resonator and two output waveguides (the through and drop ports) by the electromagnetic field calculation. We fabricated the optical switch in which the graphene microheater was directly placed on the resonator and directly observed its operation utilizing a near-infrared camera. As observed from the transmission spectra, this device exhibited high wavelength tuning efficiency of 0.24 nm/mW and high heating efficiency of 7.66 K·μm3/mW. Further, we measured the real-time high-speed operation at 100 kHz and verified that the graphene-based optical switch achieved high-speed modulation with 10%-90% rise and fall response times, 1.2 and 3.6 μs, respectively, thus confirming that they are significantly faster than typical optical switches that are based on racetrack resonators and metal heaters with response times of ∼100 μs. These graphene-based optical switches on silicon chips with high efficiency and speed are expected to enable high-performance silicon photonics and integrated optoelectronic applications.

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KW - silicon photonics

KW - silicon waveguide

KW - thermo-optic switch

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High-Speed and On-Chip Optical Switch Based on a Graphene Microheater

Abstract

Keywords

ASJC Scopus subject areas

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