Accurate core position control in polymer optical waveguides using the Mosquito method for three-dimensional optical wiring

Kumi Date, Takaaki Ishigure

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

4 Citations (Scopus)

Abstract

Polymer optical waveguides with graded-index (GI) circular cores are fabricated using the Mosquito method, in which the positions of parallel cores are accurately controlled. Such an accurate arrangement is of great importance for a high optical coupling efficiency with other optical components such as fiber ribbons. In the Mosquito method that we developed, a core monomer with a viscous liquid state is dispensed into another liquid state monomer for cladding via a syringe needle. Hence, the core positions are likely to shift during or after the dispensing process due to several factors. We investigate the factors, specifically affecting the core height. When the core and cladding monomers are selected appropriately, the effect of the gravity could be negligible, so the core height is maintained uniform, resulting in accurate core heights. The height variance is controlled in ±2 micrometers for the 12 cores. Meanwhile, larger shift in the core height is observed when the needle-tip position is apart from the substrate surface. One of the possible reasons of the needle-tip height dependence is the asymmetric volume contraction during the monomer curing. We find a linear relationship between the original needle-tip height and the core-height observed. This relationship is implemented in the needle-scan program to stabilize the core height in different layers. Finally, the core heights are accurately controlled even if the cores are aligned on various heights. These results indicate that the Mosquito method enables to fabricate waveguides in which the cores are 3-dimensionally aligned with a high position accuracy.

Original languageEnglish
Title of host publicationOptical Interconnects XVII
PublisherSPIE
Volume10109
ISBN (Electronic)9781510606593
DOIs
Publication statusPublished - 2017
EventOptical Interconnects XVII - San Francisco, United States
Duration: 2017 Jan 302017 Feb 1

Other

OtherOptical Interconnects XVII
CountryUnited States
CitySan Francisco
Period17/1/3017/2/1

Fingerprint

Polymer Waveguide
Position Control
Optical Waveguides
wiring
Position control
Optical waveguides
Electric wiring
optical waveguides
Needles
Polymers
Three-dimensional
Monomers
polymers
needles
Syringes
Liquids
monomers
Curing
Gravitation
Waveguides

Keywords

  • 3-dimensional wiring
  • Core position accuracy
  • Polymer optical waveguide

ASJC Scopus subject areas

  • Electronic, Optical and Magnetic Materials
  • Condensed Matter Physics
  • Computer Science Applications
  • Applied Mathematics
  • Electrical and Electronic Engineering

Cite this

Accurate core position control in polymer optical waveguides using the Mosquito method for three-dimensional optical wiring. / Date, Kumi; Ishigure, Takaaki.

Optical Interconnects XVII. Vol. 10109 SPIE, 2017. 101090I.

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

Date, K & Ishigure, T 2017, Accurate core position control in polymer optical waveguides using the Mosquito method for three-dimensional optical wiring. in Optical Interconnects XVII. vol. 10109, 101090I, SPIE, Optical Interconnects XVII, San Francisco, United States, 17/1/30. https://doi.org/10.1117/12.2251076
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AB - Polymer optical waveguides with graded-index (GI) circular cores are fabricated using the Mosquito method, in which the positions of parallel cores are accurately controlled. Such an accurate arrangement is of great importance for a high optical coupling efficiency with other optical components such as fiber ribbons. In the Mosquito method that we developed, a core monomer with a viscous liquid state is dispensed into another liquid state monomer for cladding via a syringe needle. Hence, the core positions are likely to shift during or after the dispensing process due to several factors. We investigate the factors, specifically affecting the core height. When the core and cladding monomers are selected appropriately, the effect of the gravity could be negligible, so the core height is maintained uniform, resulting in accurate core heights. The height variance is controlled in ±2 micrometers for the 12 cores. Meanwhile, larger shift in the core height is observed when the needle-tip position is apart from the substrate surface. One of the possible reasons of the needle-tip height dependence is the asymmetric volume contraction during the monomer curing. We find a linear relationship between the original needle-tip height and the core-height observed. This relationship is implemented in the needle-scan program to stabilize the core height in different layers. Finally, the core heights are accurately controlled even if the cores are aligned on various heights. These results indicate that the Mosquito method enables to fabricate waveguides in which the cores are 3-dimensionally aligned with a high position accuracy.

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