USTC Realizes On-chip Valley-dependent Quantum Interference

时间:2021-06-30浏览:26

The research team led by academician GUO Guangcan from University of Science and Technology of China (USTC), collaborating with the researchers from Sun Yat-sen University and Zhejiang University, realized two-photon quantum interference in the structure of valley-dependent topological insulators based on the valley Hall effect. The study was published in Physical Rdepeview Letters.

Topological photonics has an application prospect in the research field of photonic chips due to robust energy transport prosperities. The key to topological phase transition is to generate an energy gap at certain degenerate points by breaking either the time-reversal symmetry (TRS) or inversion symmetry.

By breaking the spatial inversion symmetry of the system, the valley-dependent helical edge states travel in certain directions, known as Valley-Hall effect. Hexagonal lattice photonic crystals (PCs) with inequivalent sublattices can realize the valley-dependent topological insulators. More compact and sharp bending optical circuit can be realized, contributing to device integration and robust energy.

Quantum interference, as the core of photonic quantum information, remains to be verified in topologically protected PCs chip.

The researchers in this study designed and fabricated harpoon-shaped beam splitters (HSBSs) in silicon photonic crystals. The orientation of the electromagnetic phase vortex inside PCs with hexagonal lattice structure depends on lattice structure with different topological Chern numbers and its band position, forming two topological edges of different structures.

Harpoon-shaped beam splitters in photonic quantum chip

Based on a 120-deg-bending interfaces, they realized on-chip Hong-Ou-Mandel (HOM) interference in one HSBS with a high visibility of 95.6%.

Furthermore, the researchers demonstrated generation of path-entangled state in valley-dependent quantum circuits by cascading two HSBSs.

The study provides a novel method for topological photonics especially for topological insulators, which can be applied in more complex quantum information processing.

Paper link: https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.126.230503# 

(Written by TU Bingxin, edited by LU Hongyu, USTC News Center)