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Optoelectronics on a chip.

We are pioneering the next generation connectivity solutions for the Quantum and AI era.

Explore the applications of our photonic interconnects

Our technology makes a global impact and is being adopted in the next generation optical communication networks.

Optical transceivers
Our photonic engine enables the next generation of optical transceivers to operate beyond 1.6 Tb/s.
Telecommunication
We enhance speed and reduce power consumption of optical modulators and switches that are used in telecommunication systems. Application areas are Long-Haul and Metro networks.
Radio-over-fiber
Our photonic chips allow transmission of high frequency radio signals (>40GHz) on an optical fiber, with reduced size and weight. Application areas are 5G/6G mobile networks and communication systems on satellites and aircrafts.
Quantum technologies
Fast, low loss switch fabrics are key enablers of optical quantum computers. Moreover, the wide transparency band of TFLT makes it a perfect choice for control systems of trapped-ion quantum computers.

Our technological advantage

From DC to 100 GHz
The Pockels effect embedded in TFLN and TFLT can be used to both reconfigure the state of a photonic IC, and to impart very broadband signals on an optical carrier, beyond 100 GHz modulation frequencies.
Visible and infrared light
TFLN and TFLT are transparent in the visible spectrum, where other optoelectronic materials (InP, Si) cannot guide light. This makes them the perfect choice for constructing sensors and laser sources and to build quantum computers.
No compromises
The Pockels effect induces pure phase modulation. It can be used to realize optical modulators with linear and ideal performance, without compromising the optical insertion loss of the PIC. This is a severe trade-off of competing semiconductor platforms.

Further reading

The Future of Optical Modulation
September 2024 interview with optical interconnects and integrated photonics experts, discussing advancements in optical modulators beyond standard silicon-based technologies. It explores emerging materials and integration techniques aimed at enhancing performance and expanding the capabilities of optical communication systems. D. Liang, et al., IEEE Journal of Selected Topics in Quantum Electronics, vol. 30, July-Aug. 2024
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Lithium Tantalate Photonic Integrated Circuits for Volume Manufacturing
Scientific study pioneering low-loss photonic integrated circuits (PICs) using lithium tantalate (LiTaO₃), a material already utilized in 5G radiofrequency filters. The study demonstrates that LiTaO₃ can be etched to create PICs with low propagation losses and strong electro-optical modulation, offering a scalable and cost-effective alternative to lithium niobate (LiNbO₃) for next-generation electro-optical applications. C. Wang, Z. Li, J. Riemensberger et al. Lithium tantalate photonic integrated circuits for volume manufacturing. Nature 629, 784–790 (2024).
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Optical switch with an ultralow DC drift based on thin-film lithium tantalate
Scientific study presenting an electro-optic switch built on a thin-film lithium tantalate (TFLT) platform. The authors show ultralow operating point drift, addressing a common challenge in electro-optic devices. H. Wang et al., Opt. Lett. 49, 5019-5022 (2024)
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Ultrabroadband thin-film lithium tantalate modulator for high-speed communications
In this article, the authors use a single TFLT modulator to encode and transmit data at rates faster than 400 Gbit/s, proving a similar or superior performance of the material to that of TFLN for optical interconnections. C. Wang, D. Fang, J. Zhang, A. Kotz, et al., Optica 11, 1614-1620 (2024)
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