Dependence of resonant wavelength and mechanical deformation of photonic crystal cantilever integrated with dual nano-ring resonator

Bo Li, Fu Li Hsiao, Chengkou Lee

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

We investigated photonic crystals based dual nano-ring channel drop filters which are nanomechanically tunable. The backward channel drop mechanism is explained by a proposed model. Resonant peak observed on the free stand device is located 1553.6 nm with quality factor better than 3800 at backward drop port. When this dual nano-ring is integrated at the junction between silicon cantilever and substrate, the deformation of silicon cantilever can shift the filter resonant wavelength. The 1nm wavelength shift is derived by minimum tuning force of 370nN.

Original languageEnglish
Title of host publication2010 Photonics Global Conference, PGC 2010
DOIs
Publication statusPublished - 2010 Dec 1
Event2010 Photonics Global Conference, PGC 2010 - Orchard, Singapore
Duration: 2010 Dec 142010 Dec 16

Publication series

Name2010 Photonics Global Conference, PGC 2010

Other

Other2010 Photonics Global Conference, PGC 2010
CountrySingapore
CityOrchard
Period10-12-1410-12-16

Fingerprint

Ring Resonator
Cantilever
Photonic crystals
Photonic Crystal
Resonators
resonators
photonics
Silicon
Wavelength
rings
wavelengths
Filter
crystals
Ring
filters
Wave filters
Quality Factor
shift
silicon
Q factors

All Science Journal Classification (ASJC) codes

  • Electronic, Optical and Magnetic Materials
  • Mathematical Physics
  • Atomic and Molecular Physics, and Optics

Cite this

Li, B., Hsiao, F. L., & Lee, C. (2010). Dependence of resonant wavelength and mechanical deformation of photonic crystal cantilever integrated with dual nano-ring resonator. In 2010 Photonics Global Conference, PGC 2010 [5705971] (2010 Photonics Global Conference, PGC 2010). https://doi.org/10.1109/PGC.2010.5705971
Li, Bo ; Hsiao, Fu Li ; Lee, Chengkou. / Dependence of resonant wavelength and mechanical deformation of photonic crystal cantilever integrated with dual nano-ring resonator. 2010 Photonics Global Conference, PGC 2010. 2010. (2010 Photonics Global Conference, PGC 2010).
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abstract = "We investigated photonic crystals based dual nano-ring channel drop filters which are nanomechanically tunable. The backward channel drop mechanism is explained by a proposed model. Resonant peak observed on the free stand device is located 1553.6 nm with quality factor better than 3800 at backward drop port. When this dual nano-ring is integrated at the junction between silicon cantilever and substrate, the deformation of silicon cantilever can shift the filter resonant wavelength. The 1nm wavelength shift is derived by minimum tuning force of 370nN.",
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Li, B, Hsiao, FL & Lee, C 2010, Dependence of resonant wavelength and mechanical deformation of photonic crystal cantilever integrated with dual nano-ring resonator. in 2010 Photonics Global Conference, PGC 2010., 5705971, 2010 Photonics Global Conference, PGC 2010, 2010 Photonics Global Conference, PGC 2010, Orchard, Singapore, 10-12-14. https://doi.org/10.1109/PGC.2010.5705971

Dependence of resonant wavelength and mechanical deformation of photonic crystal cantilever integrated with dual nano-ring resonator. / Li, Bo; Hsiao, Fu Li; Lee, Chengkou.

2010 Photonics Global Conference, PGC 2010. 2010. 5705971 (2010 Photonics Global Conference, PGC 2010).

Research output: Chapter in Book/Report/Conference proceedingConference contribution

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N2 - We investigated photonic crystals based dual nano-ring channel drop filters which are nanomechanically tunable. The backward channel drop mechanism is explained by a proposed model. Resonant peak observed on the free stand device is located 1553.6 nm with quality factor better than 3800 at backward drop port. When this dual nano-ring is integrated at the junction between silicon cantilever and substrate, the deformation of silicon cantilever can shift the filter resonant wavelength. The 1nm wavelength shift is derived by minimum tuning force of 370nN.

AB - We investigated photonic crystals based dual nano-ring channel drop filters which are nanomechanically tunable. The backward channel drop mechanism is explained by a proposed model. Resonant peak observed on the free stand device is located 1553.6 nm with quality factor better than 3800 at backward drop port. When this dual nano-ring is integrated at the junction between silicon cantilever and substrate, the deformation of silicon cantilever can shift the filter resonant wavelength. The 1nm wavelength shift is derived by minimum tuning force of 370nN.

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Li B, Hsiao FL, Lee C. Dependence of resonant wavelength and mechanical deformation of photonic crystal cantilever integrated with dual nano-ring resonator. In 2010 Photonics Global Conference, PGC 2010. 2010. 5705971. (2010 Photonics Global Conference, PGC 2010). https://doi.org/10.1109/PGC.2010.5705971