Technical lecture
New product release of 8-inch lithium niobate Wafer and related LNOI wafers
15. May 2024 from 14:00 to 16:00 Clock
Hall: 3.1 / Stand: 125
Tim Xu & Julie Zhu, Hangzhou Freqcontrol Electronic Technology Ltd., Hangzhou
Product group: Optical components and materials
Lithium Niobate (LiNbO3) is a useful optoelectronic material. The material not only has unique piezoelectric, optical and photoelastic properties, but also has good mechanical and chemical stability. Its combination of excellent electro-optic, acoustooptic and nonlinear optical properties makes it an attractive material in integrated optics.
CQT provides up to 8" diameter, single crystal Optical grade LN material with reduced impurity levels. Other specifications can be provided are doped wafers: Er:LN, MgO:LN and Fe:LN.
The most used SAW orientations are YZ-cut and 128°Y-cut, best fit for television transmission and reception signal processing. The 128°Y-cut with X propagation is said to have the lowest spurious signal level.
Lithium Niobate (LN) is a ferroelectric material with excellent electro-optic, nonlinear, and piezoelectric properties. Lithium niobate crystals are important materials for optical waveguides, mobile phones, piezoelectric sensors, optical modulators and various other linear and non-linear optical applications.
The largest use of Lithium Niobate (LN) is in SAW devices used in telecommunication devices. When voice communication and data communication are performed, SAW devices such as SAW filters and SAW duplexers are mounted in communication devices as filters for preventing noise and interference. Lithium Niobate (LN) crystals are also used in optical applications.
LNOI wafers are used to make high-speed electro-optic modulators, high-performance acoustic wave filters and other high-performance devices, which are widely used in data centers, long-distance data transmission, mobile phones, etc.
Advantages of thin film lithium niobate modulators :
Small size, excellent stability, large bandwidth, high transmission rate, low power consumption, and enabling optical integration.
Advantages of thin film lithium niobate SAW filters:
Ke2>25%; large bandwidth; high frequency; excellent temperature stability; high reliability; high heat dissipation performance.
Solutions to high-bandwidth and high-frequency RF device markets required for next-generation wireless networks.
CQT provides up to 8" diameter, single crystal Optical grade LN material with reduced impurity levels. Other specifications can be provided are doped wafers: Er:LN, MgO:LN and Fe:LN.
The most used SAW orientations are YZ-cut and 128°Y-cut, best fit for television transmission and reception signal processing. The 128°Y-cut with X propagation is said to have the lowest spurious signal level.
Lithium Niobate (LN) is a ferroelectric material with excellent electro-optic, nonlinear, and piezoelectric properties. Lithium niobate crystals are important materials for optical waveguides, mobile phones, piezoelectric sensors, optical modulators and various other linear and non-linear optical applications.
The largest use of Lithium Niobate (LN) is in SAW devices used in telecommunication devices. When voice communication and data communication are performed, SAW devices such as SAW filters and SAW duplexers are mounted in communication devices as filters for preventing noise and interference. Lithium Niobate (LN) crystals are also used in optical applications.
LNOI wafers are used to make high-speed electro-optic modulators, high-performance acoustic wave filters and other high-performance devices, which are widely used in data centers, long-distance data transmission, mobile phones, etc.
Advantages of thin film lithium niobate modulators :
Small size, excellent stability, large bandwidth, high transmission rate, low power consumption, and enabling optical integration.
Advantages of thin film lithium niobate SAW filters:
Ke2>25%; large bandwidth; high frequency; excellent temperature stability; high reliability; high heat dissipation performance.
Solutions to high-bandwidth and high-frequency RF device markets required for next-generation wireless networks.