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March 21, 2026

Controlling Quantum Interference via Non-Unitary Transformations in a 6-Mode Quantum Chip

Key Points

The aim is to control non-unitary transformations in a six-mode integrated photonic circuit for quantum information processing.
Development of a six-mode integrated photonic circuit with tunable loss channels
Characterization of two-photon non-unitary dynamics using singular value decomposition
Numerical simulations to analyze the impact of loss channels on the optical field distribution
Achieved precise control over non-unitary transformations in the optical system
Demonstrated how loss channels influence the spatial distribution of light
Provided a flexible approach for designing loss-engineered photonic devices

Abstract

Integrated photonic circuits are emerging as a flexible platform for advanced quantum information processing. In this work, we achieve precise and reproducible control of non-unitary transformations in a six-mode integrated photonic circuit. The system includes two independently tunable loss channels, which enable direct adjustment of the underlying dynamics. We use a singular value decomposition–based model to characterize two-photon non-unitary dynamics. Numerical simulations are then performed to examine how the loss channels affect the spatial distribution of the optical field. These results demonstrate a flexible method for controlling non-unitary optical systems and offer insights into the design of loss-engineered photonic devices and the development of advanced quantum information processing schemes.

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Cite This Study

Feng et al. (Fri,) studied this question.

synapsesocial.com/papers/69be38ca6e48c4981c679645 https://doi.org/https://doi.org/10.1142/s0218863526500189

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