Title :
Highly nonlinear bismuth-oxide fiber for supercontinuum generation and femtosecond pulse compression
Author :
Gopinath, Juliet T. ; Shen, Hanfei M. ; Sotobayashi, Hideyuki ; Ippen, Erich P. ; Hasegawa, Tomoharu ; Nagashima, Tatsuo ; Sugimoto, Naoki
Author_Institution :
Res. Lab. of Electron., Massachusetts Inst. of Technol., Cambridge, MA, USA
Abstract :
Highly nonlinear normally dispersive bismuth-oxide fiber shows promise for applications such as supercontinuum generation and femtosecond pulse compression in the telecommunications-wavelength range. To generate a wideband and flat supercontinuum spectrum, the balance between fiber nonlinearity and normal group velocity dispersion (GVD) is important. Highly nonlinear bismuth-oxide fiber exhibits a large nonlinearity due to the small effective area and nonlinear index of the host glass material. The fiber also has a relatively flat dispersion profile over a large wavelength range. Utilizing these features, we generate a smooth unstructured supercontinuum between 1200 and 1800 nm. This supercontinuum is passed through a grating pair, and pulses, originally of 150-fs length, are compressed to 25 fs.
Keywords :
bismuth compounds; high-speed optical techniques; optical fibre dispersion; optical glass; optical pulse compression; supercontinuum generation; 1200 to 1800 nm; 150 fs; 25 fs; BiO; dispersion profile; effective area; femtosecond pulse compression; fiber nonlinearity; group velocity dispersion; highly nonlinear bismuth-oxide fiber; host glass material; nonlinear index; supercontinuum generation; Glass; Nonlinear optics; Optical fibers; Optical pulse compression; Optical pulse generation; Optical pulses; Pulse amplifiers; Pulse compression methods; Supercontinuum generation; Ultrafast optics; Nonlinear fiber; nonlinear optics; pulse compression; ultrafast nonlinear optics;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2005.855872
