News Release

Enhanced wavelength conversion to advance quantum information networks

New research achieves significant bandwidth in frequency conversion, paving the way for more efficient quantum information transfer and integrated photonic systems

Peer-Reviewed Publication

SPIE--International Society for Optics and Photonics

Dispersion-designed structural geometry enables group-velocity mismatch of interacting lights to be smoothed to zero, for wide-range frequency conversion. Credit: T. Yuan, J. Wu, et al., doi 10.1117/1.AP.6.5.056012

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Dispersion-designed structural geometry enables group-velocity mismatch of interacting lights to be smoothed to zero, for wide-range frequency conversion. 

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Credit: T. Yuan, J. Wu, et al., doi 10.1117/1.AP.6.5.056012.

Advancements in quantum information technology are paving the way for faster and more efficient data transfer. A key challenge has been ensuring that qubits, the fundamental units of quantum information, can be transferred between different wavelengths without losing their essential properties, such as coherence and entanglement. As reported in Advanced Photonics, researchers from Shanghai Jiao Tong University (SJTU) recently made significant strides in this area by developing a novel method for broadband frequency conversion, a crucial step for future quantum networks.

The SJTU team focused on a technique using X-cut thin film lithium niobate (TFLN), a material known for its nonlinear optical properties. They achieved broadband second-harmonic generation—an important process for converting light from one wavelength to another—with a remarkable bandwidth of up to 13 nanometers. This was accomplished through a process called mode hybridization, which allows for precise control over the frequency conversion in a micro-racetrack resonator.

According to corresponding author Professor Yuping Chen, “An efficient second-order nonlinear process with widely-tunable pump bandwidth has been a long-pursued goal, owing to the extensive applications in wavelength division multiplexing networks, ultrashort pulse nonlinearity, quantum key distribution, and broadband single-photon source generation.” She adds, “Thanks to the great progress in fabrication technology on the TFLN platform, this work will pave the way to chip-scale nonlinear frequency conversion between the ultrashort optical pulses and even the quantum states.”  

This breakthrough could have wide-ranging implications for integrated photonic systems. By enabling on-chip tunable frequency conversion, it opens the door to enhanced quantum light sources, larger capacity multiplexing, and more effective multichannel optical information processing. As researchers continue to explore these technologies, the potential for expanding quantum information networks grows, bringing us closer to realizing their full capabilities in various applications.


For details, see the original Gold Open Access article by T. Yuan, J. Wu, et al., “Chip-scale nonlinear bandwidth enhancement via birefringent mode hybridization,” Adv. Photon6(5), 056012 (2024), doi 10.1117/1.AP.6.5.056012.


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