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Periodic Poled Lithium Niobate Ridge Waveguide Devices
Classification:
The most commonly used preparation methods of lithium niobate optical waveguides are proton exchange method and metal diffusion method, because the refractive index difference between the waveguide and the substrate layer of the waveguide device prepared by these two methods is small, the limiting effect on light is weak, and the foreign ions introduced in the production process will destroy the properties of the lithium niobate crystal itself, thus affecting the performance of the waveguide. The ridge waveguide structure based on lithium niobate single crystal thin film (LNOI) greatly increases the refractive index difference between the core and shell of the waveguide, so the optical confinement effect of the waveguide is enhanced, which can improve the nonlinear effect in the lithium niobate waveguide. In addition, the optical damage threshold of the lithium niobate ridge waveguide is higher, which is suitable for the production of high-power frequency conversion devices.
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The most commonly used preparation methods of lithium niobate optical waveguides are proton exchange method and metal diffusion method, because the refractive index difference between the waveguide and the substrate layer of the waveguide device prepared by these two methods is small, the limiting effect on light is weak, and the foreign ions introduced in the production process will destroy the properties of the lithium niobate crystal itself, thus affecting the performance of the waveguide. The ridge waveguide structure based on lithium niobate single crystal thin film (LNOI) greatly increases the refractive index difference between the core and shell of the waveguide, so the optical confinement effect of the waveguide is enhanced, which can improve the nonlinear effect in the lithium niobate waveguide. In addition, the optical damage threshold of the lithium niobate ridge waveguide is higher, which is suitable for the production of high-power frequency conversion devices.
Main Features Features
Non-linear frequency conversion such as SHG/SFG/DFG can be realized
High efficiency coupling between fiber and chip
High conversion efficiency
High Damage Threshold
Good long-term stability
Application field Applications
high power single frequency laser
quantum secure communication
Lidar
optical sensing
High power 1560nm frequency doubling waveguide output power curve:

Overall dimensions:

Main technical indicators:
Parameters
Unit
Numerical
Optics
Input Optical Wavelength
nm
1560
frequency doubling optical wavelength
nm
780
Output power
W
2
Polarization Extinction Ratio (PER)
dB
≥20
Electricity
Thermoelectric cooler
4.4V, 1.5A maximum,
Qc = 4.1 W
NTC Impedance @ 25 ℃
KΩ
10
Mechanical
incoming and outgoing fiber
-
PM1550 PM780
Environment
Working temperature
℃
10~ 35
Storage temperature
℃
-20~ 70
-
Model
Main features
Application areas
Low insertion loss
Low drive voltage
DC bias and RF signal separation to ensure long-term stability
High switch extinction ratio
Meets GR-468-CORE standards
10 Gb/s high-speed transmission equipment
TDM and WDM10Gb/s Transmission System
40 Gb/s, 80 Gb/s coherent transmission system
Lithium Niobate Multifunctional Integrated Optics (Y-Waveguide)
Ultra-small package size, light weight
Low-loss X-cut Y-transmission lithium niobate optical waveguide
Fabrication of waveguide by annealing proton exchange process, single polarization operation, high chip polarization extinction ratio
Push-pull electrode design to reduce half-wave voltage
Good long-term stability of the device
Fiber Optic Gyroscope (FOG)
Fiber Optic Current Sensor (FOCS)
Hydrophone and other fiber optic sensing fields
Periodic Poled Lithium Niobate (PPLN) Crystal
For use in the visible to mid-infrared wavelength range
Can realize SHG/SFG/DFG and other nonlinear frequency conversion
Change
uniform periodic polarization structure
Precision Waveguide End Surface Polishing and Coating
High Damage Threshold
electric laser display
mid-infrared spectroscopy
all-optical wavelength conversion
optical sensing
scientific research and medical treatment
Environmental detection
Non-linear frequency conversion such as SHG/SFG/DFG can be realized
High efficiency coupling between fiber and chip
High conversion efficiency
High Damage Threshold
Good long-term stability
high power single frequency laser
quantum secure communication
Lidar
optical sensing
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E-mail: sales@fiberlink.com.cn
Address: Building 1, No. 12 Miaoshan East Road, Jiangxia District, Wuhan, Hubei Province, 430073 P.R China
