Evanescent light enhancement in a nanometer aperture surrounded by corrugated metal thin film for a terabyte optical disk head

Kenya Goto; Takahito Ono; Yong Joo Kim

doi:10.1109/TMAG.2004.842031

Evanescent light enhancement in a nanometer aperture surrounded by corrugated metal thin film for a terabyte optical disk head

Kenya Goto, Takahito Ono, Yong Joo Kim

ENG - Mechanical Systems Engineering

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

10 Citations (Scopus)

Abstract

An ultrahigh density optical disk head which utilizes evanescent light (near-field light) had been designed to enhance the near-field optical wave for the throughput increment using the surface plasmon polariton resonance effect between the light inside the near-field optical head and nano-fabricated corrugated metal thin film. The theoretical analysis is discussed with the emphasis on the two- and three-dimensional simulation using finite difference time domain method. It is also experimentally shown that the near-field light enhancement in a waveguide of a clad covered with corrugated gold thin film was observed and that the near-field light enhancement in a waveguide without the film was not. If the corrugation pitch and the focused laser wavelength used with self-aligned microlens are designed properly, more than 20% throughput will be realized using nanometer fabricated metallic grating.

Original language	English
Pages (from-to)	1037-1041
Number of pages	5
Journal	IEEE Transactions on Magnetics
Volume	41
Issue number	2
DOIs	https://doi.org/10.1109/TMAG.2004.842031
Publication status	Published - 2005 Feb

Keywords

Evanescent wave
Nano-aperture
Nano-fabrication
Near-field optics
Surface plasmon
Terabyte optical memory

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10.1109/TMAG.2004.842031

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title = "Evanescent light enhancement in a nanometer aperture surrounded by corrugated metal thin film for a terabyte optical disk head",

abstract = "An ultrahigh density optical disk head which utilizes evanescent light (near-field light) had been designed to enhance the near-field optical wave for the throughput increment using the surface plasmon polariton resonance effect between the light inside the near-field optical head and nano-fabricated corrugated metal thin film. The theoretical analysis is discussed with the emphasis on the two- and three-dimensional simulation using finite difference time domain method. It is also experimentally shown that the near-field light enhancement in a waveguide of a clad covered with corrugated gold thin film was observed and that the near-field light enhancement in a waveguide without the film was not. If the corrugation pitch and the focused laser wavelength used with self-aligned microlens are designed properly, more than 20% throughput will be realized using nanometer fabricated metallic grating.",

keywords = "Evanescent wave, Nano-aperture, Nano-fabrication, Near-field optics, Surface plasmon, Terabyte optical memory",

author = "Kenya Goto and Takahito Ono and Kim, {Yong Joo}",

note = "Funding Information: Manuscript received September 21, 2004. This work was supported in part by the Japan Society for the Promotion of Science under Grant-in-Aid for Scientific Research 16560037. K. Goto is with Tokai University, Shizuoka 410-0395, Japan (e-mail: kenya@tokai.ac.jp). T. Ono is with Tohoku University, Sendai 980-8579, Japan (e-mail: tono@mech.cc.tohoku-u.ac.jp). Y.-J. Kim is with Yonsei University, Seoul 120-749, Korea (e-mail: yjkim40@yonsei.ac.kr). Digital Object Identifier 10.1109/TMAG.2004.842031 Fig. 1. Cross-sectional view of the new near-field optical head structure, which consists of 2-D VCSEL, micro-lens (10 m ) that is covered with corrugated metallic film, and 30 nm aperture array.",

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T1 - Evanescent light enhancement in a nanometer aperture surrounded by corrugated metal thin film for a terabyte optical disk head

AU - Goto, Kenya

AU - Ono, Takahito

AU - Kim, Yong Joo

N1 - Funding Information: Manuscript received September 21, 2004. This work was supported in part by the Japan Society for the Promotion of Science under Grant-in-Aid for Scientific Research 16560037. K. Goto is with Tokai University, Shizuoka 410-0395, Japan (e-mail: kenya@tokai.ac.jp). T. Ono is with Tohoku University, Sendai 980-8579, Japan (e-mail: tono@mech.cc.tohoku-u.ac.jp). Y.-J. Kim is with Yonsei University, Seoul 120-749, Korea (e-mail: yjkim40@yonsei.ac.kr). Digital Object Identifier 10.1109/TMAG.2004.842031 Fig. 1. Cross-sectional view of the new near-field optical head structure, which consists of 2-D VCSEL, micro-lens (10 m ) that is covered with corrugated metallic film, and 30 nm aperture array.

PY - 2005/2

Y1 - 2005/2

N2 - An ultrahigh density optical disk head which utilizes evanescent light (near-field light) had been designed to enhance the near-field optical wave for the throughput increment using the surface plasmon polariton resonance effect between the light inside the near-field optical head and nano-fabricated corrugated metal thin film. The theoretical analysis is discussed with the emphasis on the two- and three-dimensional simulation using finite difference time domain method. It is also experimentally shown that the near-field light enhancement in a waveguide of a clad covered with corrugated gold thin film was observed and that the near-field light enhancement in a waveguide without the film was not. If the corrugation pitch and the focused laser wavelength used with self-aligned microlens are designed properly, more than 20% throughput will be realized using nanometer fabricated metallic grating.

AB - An ultrahigh density optical disk head which utilizes evanescent light (near-field light) had been designed to enhance the near-field optical wave for the throughput increment using the surface plasmon polariton resonance effect between the light inside the near-field optical head and nano-fabricated corrugated metal thin film. The theoretical analysis is discussed with the emphasis on the two- and three-dimensional simulation using finite difference time domain method. It is also experimentally shown that the near-field light enhancement in a waveguide of a clad covered with corrugated gold thin film was observed and that the near-field light enhancement in a waveguide without the film was not. If the corrugation pitch and the focused laser wavelength used with self-aligned microlens are designed properly, more than 20% throughput will be realized using nanometer fabricated metallic grating.

KW - Evanescent wave

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Evanescent light enhancement in a nanometer aperture surrounded by corrugated metal thin film for a terabyte optical disk head

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