Above-Bandgap Surface-Emitting Frequency Conversion in Semiconductor Nanoribbons With Ultralow Continuous-Wave Pump Power

Author

Fuxing Gu ; Guoqing Wu ; Li Zhang ; Heping Zeng

Author_Institution

Eng. Res. Center of Opt. Instrum. & Syst., Univ. of Shanghai for Sci. & Technol., Shanghai, China

Volume

21

Issue

1

fYear

2015

fDate

Jan.-Feb. 2015

Firstpage

480

Lastpage

485

Abstract

Semiconductors have large optical nonlinear susceptibilities especially in the spectral range above material bandgaps. However, optical frequency conversion encounters large absorption above bandgaps and difficulty using common phase-matching techniques. The frequency conversion bandwidths are thus limited. Here, frequency up-conversion far above the bandgaps using surface emissions from semiconductor nanoribbons is demonstrated, wherein nanoscale waveguiding tightly confines fundamental waves for decreasing pump powers, and above-bandgap absorption is greatly decreased in nanoscale waveguide thickness. By using CdSe nanoribbons, efficient 532- and 404-nm second-harmonic and 459-nm sum-frequency generations are obtained with the continuous-wave pump power less than 100 μW. The normalized efficiency of 532-nm second-harmonic generation is about 2 × 10^-5 mm^-1 at pump power of 300 μW. Attractive features such as tunable spatial distribution and highly polarization are observed. A broadband emission with a full width half maximum of ~10 nm is attained by frequency summing a continuous-wave laser and an amplified spontaneous emission source.

Keywords

II-VI semiconductors; cadmium compounds; light absorption; nanophotonics; nanoribbons; optical harmonic generation; optical pumping; optical tuning; optical waveguides; superradiance; wide band gap semiconductors; CdSe; above-bandgap absorption; above-bandgap surface-emitting frequency conversion; amplified spontaneous emission source; broadband emission; continuous-wave laser; frequency up-conversion; full width half maximum; nanoscale waveguide thickness; nanoscale waveguiding; polarization; power 300 muW; second-harmonic generation; semiconductor nanoribbons; sum-frequency generation; tunable spatial distribution; ultralow continuous-wave pump power; wavelength 404 nm; wavelength 532 nm; Frequency conversion; Nonlinear optics; Optical harmonic generation; Optical pumping; Pump lasers; Surface emitting lasers; Semiconductor nanoribbons; above bandgap; second harmonic generation; sum frequency generation; surface emitting;

fLanguage

English

Journal_Title

Selected Topics in Quantum Electronics, IEEE Journal of

Publisher

ieee

ISSN

1077-260X

Type

jour

DOI

10.1109/JSTQE.2014.2354644

Filename

6891168