Abstract: A method for preparing a periodically poled structure comprises the steps of providing a ferroelectric substrate having an upper surface and a bottom surface, forming an upper electrode including at least one first block and at least one second block on the upper surface, forming a bottom electrode including at least one third block and at least one fourth block on the bottom surface and performing a plurality of poling processes to form at least one first domain and at least one second domain in the ferroelectric substrate, wherein the first domain is formed between the first block and the third block, and the second domain is formed between the second block and the fourth block.

Abstract: A wavelength converter structure according to one aspect of the present invention comprises a ferroelectric substrate, a ridge positioned on the ferroelectric substrate, a plurality of first domains positioned in the ridge and a plurality of second domains interleaved between the first domains in the ridge. The first domains have a first polarization direction and the second domains have a second polarization direction opposite to the first polarization direction. The refraction index of the ferroelectric substrate is different from the refraction index of the ridge. The ridge may include a rectangular portion, a taper portion, or a taper portion and a rectangular portion connected to the taper portion.

Abstract: A method for preparing a periodically poled structure comprises the steps of applying a predetermined voltage to first conductive blocks on a ferroelectric substrate such that a plurality of first domains having a first polarization direction are formed in the ferroelectric substrate and applying the predetermined voltage to second conductive blocks on the ferroelectric substrate such that a plurality of second domains having the first polarization direction are formed in the ferroelectric substrate between the first domains. In addition, the method may further comprises a step of applying the predetermined voltage to a third conductive blocks between the first conductive blocks and the second conductive blocks such that a plurality of third domains having the first polarization direction are formed in the ferroelectric substrate between the first domains and the second domains.

Abstract: A wavelength converter structure according to one aspect of the present invention comprises a ferroelectric substrate, a ridge positioned on the ferroelectric substrate, a plurality of first domains positioned in the ridge and a plurality of second domains interleaved between the first domains in the ridge. The first domains have a first polarization direction and the second domains have a second polarization direction opposite to the first polarization direction. The refraction index of the ferroelectric substrate is different from the refraction index of the ridge. The ridge may include a rectangular portion, a taper portion, or a taper portion and a rectangular portion connected to the taper portion.

Abstract: A periodic poling structure comprises a ferroelectric substrate including a plurality of tunnels, a plurality of first domains positioned in the ferroelectric substrate between the tunnels and a plurality of second domains interleaved between the first domains in the ferroelectric substrate. Each first domain has a first polarization direction, and each second domain has a second polarization direction different from the first polarization direction. The tunnels are disposed on a top surface and on a bottom surface of the ferroelectric substrate in an equal interval manner or in a variant interval manner. Particularly, the second polarization direction is opposite to the first polarization direction. The periodic poling structure further comprises a plurality of conductive blocks covering the entire base surfaces of the tunnels, or separated from the sidewalls of the tunnels by insulation gaps such that the conductive blocks cover only a portion of the base surfaces of the tunnels.

Abstract: An optical frequency mixer according to one embodiment of the present invention comprises a V-shaped resonant cavity including a first reflective surface, a second reflective surface and an output coupler, a pumping unit configured to emit a pumping wave to the laser gain medium to generate a resonating wave in the resonant cavity, a nonlinear crystal positioned on an optical path of the resonating wave in the resonant cavity, and an input interface configured to emit a mixing wave into the resonant cavity. Preferably, the output coupler can be a plano-concave lens having a concave surface configured to reflect the resonating wave and to focus the resonating wave such that the spot size of the resonating wave is matched the spot size of the pumping wave. Particularly, the nonlinear crystal is positioned between the output coupler and the input interface.

Abstract: An optical frequency mixer according to one embodiment of the present invention comprises a V-shaped resonant cavity including a first reflective surface, a second reflective surface and an output coupler, a pumping unit configured to emit a pumping wave to the laser gain medium to generate a resonating wave in the resonant cavity, a nonlinear crystal positioned on an optical path of the resonating wave in the resonant cavity, and an input interface configured to emit a mixing wave into the resonant cavity. Preferably, the output coupler can be a plano-concave lens having a concave surface configured to reflect the resonating wave and to focus the resonating wave such that the spot size of the resonating wave is matched the spot size of the pumping wave. Particularly, the nonlinear crystal is positioned between the output coupler and the input interface.