Soliton-self-frequency-shift effects and pulse compression in an anomalously dispersive high nonlinearity lead silicate holey fiber

We report the fabrication of a single-mode lead silicate glass holey fiber with anomalous dispersion and a record nonlinearity of γ=640 W-1K-1 at 1550nm. We report what we believe to be the first soliton and pulse compression experiments in this new class of fibers

High nonlinearity extruded single-mode holey optical fibers

We report the fabrication of the first microstructured single-mode non-silica glass fiber from an extruded preform. The measured effective nonlinearity (γ) is 550 W-1 km-1, more than 500 times larger than standard silica fiber

Extrusion of high nonlinearity single-mode holey optical fibers

Holey fibers with high nonlinearity have great potential for the development of a compact devices based on nonlinear effects operating at low power. Holey fibers have been made conventionally by stacking of capillaries. We have used a novel extrusion method to produce microstructured performs and we have successfully fabricated the first microstructured single-mode non-silica glass fiber. Good dimensional control and surface finished of preforms can be achieved through the optimization of the extrusion parameters such as temperature, pressure, shear strain rate and die design. Hence die swell and "melt fracture" are avoided. The microstructure holey fiber is fabricated by canning of the extruded microstructured preform. The cane is inserted to the extruded jacket tube and the assembly is drawn into fiber. The measured effective nonlinearity = 540 W-1km-1. Which is more than 500 times larger than standard silica fiber

Extruded single-mode non-silica glass holey optical fibres

The fabrication of the first microstructured singlemode non-silica optical fibre is reported. Extrusion has been used for the first time to produce the microstructured fibre preform. The final drawn fibre has an effectively air-suspended 2 µm core. Singlemode guidance is observed from 633-1500 n