Quantum Integrated Photonics

We explore the frontier of quantum integrated photonics, developing the essential building blocks for the next generation of quantum computers.

Our research focuses on creating robust, error-resilient photonic devices that leverage quantum-control design schemes and inherent symmetries to guide quantum propagation dynamics and enable fault-tolerant computation.

Through the design and experimental validation of novel photonic architectures, we generate, manipulate, and measure quantum states of light in a more resilient and controllable way.

Positioned at the intersection of fundamental physics and advanced engineering, our work transforms deep quantum principles into scalable technologies for the emerging era of quantum integrated photonics.

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Sub Research Themes

Composite Directional Couplers

We pioneered a new approach that overcomes this limitation by dividing the coupler into carefully engineered segments

Simulation of Directional Couplers

In our work, we identified microscopic voids and density variations within the oxide cladding as a key source of these discrepancies

Automated Accurate Chip Measurement

To meet this challenge, we developed a fully automated characterization platform that integrates piezoelectric actuators

Quantum Integrated Photonics

Sub Research Themes

Composite Directional Couplers

Simulation of Directional Couplers

Automated Accurate Chip Measurement

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