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Two-dimensional absolute photonic band gaps in the visible

✍ Scribed by A. Barra; D. Cassagne; C. Jouanin

Publisher: Elsevier Science
Year: 1999
Tongue: English
Weight: 49 KB
Volume: 25
Category: Article
ISSN: 0749-6036
DOI: 10.1006/spmi.1998.0679

No coin nor oath required. For personal study only.

✦ Synopsis

The most promising two-dimensional photonic crystals are the graphite lattice of dielectric rods in air background and the triangular lattice of air holes in dielectric background. In this paper, we compare their convenience in achieving structures which inhibit the propagation of visible electromagnetic waves. For visible waves, etching is difficult because the structure period must be smaller than the light wavelength. Furthermore, the semiconductor materials whose electronic band gap does not absorb any optical waves have little dielectric constant, which reduces photonic band gap widths. We show, using the Plane Wave Method and the Transfer Matrix Method, that the triangular structure is not appropriate because its gap is too narrow and its dimensions are too small for fabrication. On the other hand, wider gaps and larger dimensions that should be etched easily in wide gap semiconductors make graphite a much more suitable structure.

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