As a pioneer in photonic innovation, Neon proudly introduces its Thin-Film Lithium Niobate (TFLN) Modulator, engineered to meet the rigorous demands of next-generation optical communications, advanced radar systems, and ultra-high-speed data networks.
By leveraging the latest thin-film lithium niobate (TFLN) photonics technology, Neon overcomes the limitations of traditional bulk LiNbO₃ modulators. Through precise fabrication of low-loss submicron waveguides, we deliver ultra-compact devices that outperform conventional silicon and indium phosphide (InP) solutions—especially at similar half-wave voltage levels.
Our modulators are equipped with finely tuned traveling-wave electrodes, achieving electro-optic bandwidths beyond 100 GHz. This makes them ideal for environments that demand rapid signal processing, minimal latency, and maximum throughput.
Ultra-Compact and Highly Integrated
Designed for tight integration into photonic integrated circuits (PICs), reducing footprint and enhancing scalability.
Ultra-High Bandwidth (>100 GHz)
Perfect for high-speed platforms including 5G, 6G, and future optical interconnects.
Outstanding Linearity and Signal Fidelity
Enables clean, distortion-free modulation for mission-critical and high-performance applications.
Low Insertion Loss & Energy Efficient
Reduces system loss and power consumption, improving overall cost-efficiency.
CMOS-Compatible Fabrication
Ensures smooth integration with existing semiconductor manufacturing processes, supporting volume production and system-level integration.
Reliable Performance in Harsh Environments
Built for long-term stability and durability under a wide range of operating conditions.
Whether you're building cutting-edge optical communication systems, expanding data center capacity, developing quantum photonics, or enhancing LIDAR or precision sensors, Neon’s TFLN modulators provide the performance and reliability you need.
Choose Neon – the partner you can count on for high-speed, high-precision photonic components that power the technologies of tomorrow.