We designed and manufactured an optical bistability waveguide device based on nonlinear one-dimensional photonic crystal used CdS

x

Se

1-x

doped glass. This kind of semiconductor doped glass has large nonlinear refractive index and nonlinear fast response time. The distribution of refractive index of the nonlinear one-dimensional photonic crystal waveguide satisfies sine function. We obtained the nonlinear photonic crystal waveguide by exposure holography and etching techniques. Length of the photonic crystal waveguide is about 3 mm. The height of the peak-groove of the waveguide is 0.1 m. According to our design

the center of bandgap of the one-dimensional photonic crystal lies at 514.5 nm while the power density of the incident light

the incident light was reflected by the photonic crystal. When the power density of the incident light increasing

the bandgap is shifting to the direc-tion of short wavelength due to the decreasing of the refractive index with the increasing of the incident power density

so more incident light is transmitted. In experiment

we used an active mode-locking pulse of Ar ion laser as the light source which wavelength is 514.5 nm

repeating frequency is 82 MH z and pulse width is 200 ps. The light beam was coupled into the device by prism with a laser average power of 1.28 W (in the case of nonlinear saturation operation

optimum coupling efficiency is about 6%). Pulse wave forms of incident light and transmitted from sample were recorded in turn by 7904 oscilloscope. The optical bistability curve of input power density and output one is fitted by computer. We obtained the threshold power density of bistable switch to be 1.6010

5

W/cm

2

(it is equivalent to average power of 77 mW) and both the rise and fall time are 63 ps. We used the Finite Difference Time Domain Method to obtain the characteristics of the bandgap shift with the incident power density increasing of the nonlinear photonic crystal and calculate the optical bistability curve of this device. In theory

the threshold power density of bistable switch is about 1.4010

5

W/cm

2

and the switch time is about 50 ps. The theoretical results agree well with the experimental ones. This device is a new and feasible one for optical information process and optical computing in the future.