Optical visible wavelength region selective reflector design for photovoltaic cells using photonic crystal

The development of an efficient silicon-based nanolight source is an important step for silicon-based photonic integrated circuits. We propose a high quality factor photonic crystal nanocavity consisting of silicon and silica, which can be used as a silicon-compatible nanolight source. We show that this cavity can effectively confine lights in a low-index silica layer with a high confinement factor of 0.25, in which rare-earth dopants can be embedded as gain materials. The cavity is optimized to have a high quality factor of 15,000 and a mode volume of 0.01 μm3, while the resonance has a wavelength of 1537 nm. We expect that the high confinement factor in the thin silica layer and the high quality factor of the proposed cavity enable the cavity to be a good candidate for silicon-compatible nanolight sources for use in nanolasers or light-emitting diodes in the telecommunication wavelength region.

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IR-to-visible wavelength-band translation in photonic crystal fiber

SPIE Newsroom ◽

10.1117/2.1200607.0294 ◽

2006 ◽

Author(s):

Stojan Radic

Keyword(s):

Photonic Crystal ◽

Photonic Crystal Fiber ◽

Wavelength Band ◽

Crystal Fiber ◽

Visible Wavelength

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Tunable wavelength conversion based on optofluidic infiltrated photonic crystal fibers

Journal of Nonlinear Optical Physics & Materials ◽

10.1142/s0218863519500024 ◽

2019 ◽

Vol 28 (01) ◽

pp. 1950002 ◽

Cited By ~ 1

Author(s):

H. Pakarzadeh ◽

R. Derakhshan ◽

S. Hosseinabadi

Keyword(s):

Photonic Crystal ◽

Wavelength Conversion ◽

Photonic Crystal Fibers ◽

Wavelength Region ◽

Anomalous Dispersion ◽

Index Formula ◽

Wavelength Shift ◽

Dispersion Properties ◽

Dispersion Regime ◽

Crystal Fibers

In this paper, wavelength conversion based on optofluidic infiltration of photonic crystal fibers (PCFs) is investigated to achieve the suitable wavelength over wide tunable range. For this purpose, two designs of PCFs (the so-called PCF1 and PCF2) with appropriate dispersion properties are simulated, and wavelength conversion via four-wave mixing process for pump wavelengths in both normal and anomalous dispersion regimes is studied. By changing the refractive index [Formula: see text] of the optical fluid infiltrated into the PCF air-holes and then varying the fiber dispersion properties, the converted wavelength region can be tuned. The results show that for the pump wavelength in the normal dispersion regime, the PCF1 infiltrated with [Formula: see text] and PCF2 infiltrated with [Formula: see text] exhibit the maximum wavelength shift. Moreover, the wavelength shift is much higher than that obtained in the anomalous dispersion regime and it can be further increased by increasing the input pump power.

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