Slow-light-enhanced energy efficiency for graphene microheaters on silicon photonic crystal waveguides

Siqi Yan; Xiaolong Zhu; Lars Hagedorn Frandsen; Sanshui Xiao; N. Asger Mortensen; Jianji Dong; Yunhong Ding

doi:10.1038/ncomms14411

Slow-light-enhanced energy efficiency for graphene microheaters on silicon photonic crystal waveguides

Siqi Yan
, Xiaolong Zhu
, Lars Hagedorn Frandsen
, Sanshui Xiao
, N. Asger Mortensen
, Jianji Dong^*
, Yunhong Ding

^*此作品的通讯作者

Huazhong University of Science and Technology
Technical University of Denmark

科研成果: 期刊稿件 › 文章 › 同行评审

197 引用（Scopus）

摘要

Slow light has been widely utilized to obtain enhanced nonlinearities, enhanced spontaneous emissions and increased phase shifts owing to its ability to promote light-matter interactions. By incorporating a graphene on a slow-light silicon photonic crystal waveguide, here we experimentally demonstrate an energy-efficient graphene microheater with a tuning efficiency of 1.07 nmmW^-1 and power consumption per free spectral range of 3.99 mW. The rise and decay times (10-90%) are only 750 and 525 ns, which, to the best of our knowledge, are the fastest reported response times for microheaters in silicon photonics. The corresponding figure of merit of the device is 2.543 nW s, one order of magnitude better than results reported in previous studies. The influence of the length and shape of the graphene heater to the tuning efficiency is further investigated, providing valuable guidelines for enhancing the tuning efficiency of the graphene microheater.

源语言	英语
文章编号	14411
期刊	Nature Communications
卷	8
DOI	https://doi.org/10.1038/ncomms14411
出版状态	已出版 - 9 2月 2017
已对外发布	是

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10.1038/ncomms14411

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abstract = "Slow light has been widely utilized to obtain enhanced nonlinearities, enhanced spontaneous emissions and increased phase shifts owing to its ability to promote light-matter interactions. By incorporating a graphene on a slow-light silicon photonic crystal waveguide, here we experimentally demonstrate an energy-efficient graphene microheater with a tuning efficiency of 1.07 nmmW-1 and power consumption per free spectral range of 3.99 mW. The rise and decay times (10-90\%) are only 750 and 525 ns, which, to the best of our knowledge, are the fastest reported response times for microheaters in silicon photonics. The corresponding figure of merit of the device is 2.543 nW s, one order of magnitude better than results reported in previous studies. The influence of the length and shape of the graphene heater to the tuning efficiency is further investigated, providing valuable guidelines for enhancing the tuning efficiency of the graphene microheater.",

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AU - Yan, Siqi

AU - Zhu, Xiaolong

AU - Frandsen, Lars Hagedorn

AU - Xiao, Sanshui

AU - Mortensen, N. Asger

AU - Dong, Jianji

AU - Ding, Yunhong

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Y1 - 2017/2/9

N2 - Slow light has been widely utilized to obtain enhanced nonlinearities, enhanced spontaneous emissions and increased phase shifts owing to its ability to promote light-matter interactions. By incorporating a graphene on a slow-light silicon photonic crystal waveguide, here we experimentally demonstrate an energy-efficient graphene microheater with a tuning efficiency of 1.07 nmmW-1 and power consumption per free spectral range of 3.99 mW. The rise and decay times (10-90%) are only 750 and 525 ns, which, to the best of our knowledge, are the fastest reported response times for microheaters in silicon photonics. The corresponding figure of merit of the device is 2.543 nW s, one order of magnitude better than results reported in previous studies. The influence of the length and shape of the graphene heater to the tuning efficiency is further investigated, providing valuable guidelines for enhancing the tuning efficiency of the graphene microheater.

AB - Slow light has been widely utilized to obtain enhanced nonlinearities, enhanced spontaneous emissions and increased phase shifts owing to its ability to promote light-matter interactions. By incorporating a graphene on a slow-light silicon photonic crystal waveguide, here we experimentally demonstrate an energy-efficient graphene microheater with a tuning efficiency of 1.07 nmmW-1 and power consumption per free spectral range of 3.99 mW. The rise and decay times (10-90%) are only 750 and 525 ns, which, to the best of our knowledge, are the fastest reported response times for microheaters in silicon photonics. The corresponding figure of merit of the device is 2.543 nW s, one order of magnitude better than results reported in previous studies. The influence of the length and shape of the graphene heater to the tuning efficiency is further investigated, providing valuable guidelines for enhancing the tuning efficiency of the graphene microheater.

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Slow-light-enhanced energy efficiency for graphene microheaters on silicon photonic crystal waveguides

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