High-Q Weakly Modulated Nanobeam Cavity Based on a Suspended Silicon Dioxide Waveguide
Photonic crystal(PhC)cavities have drawn plenty of attentions during the past several decades for the advantages of ultra-high Q factor and small mode volume.PhC cavities have various applications such as quantum information processing,low threshold lasers,optomechanics,and nonlinear optics.PhC cavities based on silicon material have been heavily investigated due to their compatibility with complementary metal-oxide-semiconductor(CMOS)technology,small feature size and low cost.However,apart from the advantage of high Q factor,silicon based PhC cavities suffer from the drawbacks of high insertion loss because of the mode mismatch with fiber and relatively low sensitivity especially for the sensing application.On the other hand,silicon dioxide(silica)waveguide experience relatively smaller loss and owns a similar refractive index to numerous liquid materials to be detected,which will leads to high sensitivity for a silica based PhC cavity sensor.In this paper,we propose a high Q factor(Q = 15500)silica based PhC nanobeam cavity with high sensitivity(the wavelength shift per refractive in-dex unit(RIU)is S = 338 nm/RIU)at the telecommunication wavelength(1550 nm).Since the refractive index contrast for silica waveguide is low for the realization of the photonic bandgaps,it is essential to utilize a silica waveguide suspended in free space.The PhC nanobeam cavity is then formed by etching a series of elliptical holes,whose dimensions linearly decrease from the center to both ends,directly into the silica waveguide.For the sake of high transmission on-resonance wavelength while maintaining high Q factor,its important to etch partly into the waveguide,which results in a low-refractive-index perturbation structure.The calculated on-resonance transmission is about 0.26.The novel proposed PhC nanobeam cavity shows a sensitivity 3 times larger than the one based on silicon counterparts and outperforms other low-index-contrast PhC cavities by a higher on-resonance transmission.Such a structure can also be used in spectrally filtering system and nonlinear optics.
Senlin Zhang Sailing He
Centre for Optical and Electromagnetic Research JORCEP Sino-Sweden Joint Research Center of PhotonicsState Key Laboratory for Modern Optical Instrumentation,East Building No.5 Zijingang Campus,Zhejiang University,Hangzhou 310058,China
国际会议
Progress in Electromagnetics Research Symposium 2014(2014年电磁学研究新进展学术研讨会)
广州
英文
1795-1798
2014-08-01(万方平台首次上网日期,不代表论文的发表时间)