Title :
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
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;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2014.2354644
