A permanent optical storage medium exhibiting ultrahigh contrast, superior stability, and a broad working wavelength regime | Zendy

ShaoChin Tseng | Zendy; HsuenLi Chen | Zendy; Haw-Woei Liu | Zendy; Chen-Chieh Yu | Zendy; Lon Alex Wang | Zendy; Yung-Pin Chen | Zendy

Open Access

A permanent optical storage medium exhibiting ultrahigh contrast, superior stability, and a broad working wavelength regime

Author(s) -

ShaoChin Tseng,

HsuenLi Chen,

Haw-Woei Liu,

Chen-Chieh Yu,

Lon Alex Wang,

Yung-Pin Chen

Publication year - 2011

Publication title -

physical chemistry chemical physics

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.053

H-Index - 239

eISSN - 1463-9084

pISSN - 1463-9076

DOI - 10.1039/c0cp02289f

Subject(s) - materials science , optical storage , finite difference time domain method , anti reflective coating , ultraviolet , optoelectronics , broadband , optics , contrast (vision) , wavelength , nanotechnology , coating , physics

In this paper we demonstrate an optical storage medium having advantages of ultrahigh contrast, superior stability, and broadband working wavelengths. Combining a single shot of deep-ultraviolet (UV) laser illumination with a Au particle-assisted etching process, we formed broadband antireflective, one-dimensional silicon nanowire arrays (SiNWs) with selectively at specific positions. Optical measurements and three-dimensional finite-difference time domain (3D-FDTD) simulations revealed ultrahigh reflection contrast between the Au and the SiNWs for both far- and near-field regimes. Relative to typical organic-based storage media, Au films and SiNWs are more stable, both chemically and thermally; therefore, we suspect that this new storage medium would exhibit high stability toward moisture, sunshine, and elevated temperatures.

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