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Phase-sensitive wave function collapse in two-photon spin Hall effect

Minggui Liang, Qiuying Li, Yichang Shou, Jiawei Liu, Shizhen Chen, Weixing Shu, Shuangchun Wen, Hailu Luo

2025Advanced Photonics6 citationsDOIOpen Access PDF

Abstract

Photonic spin Hall effect (SHE) is a fundamental and important optical phenomenon, which originates from the spin–orbit interactions (SOI) of light, forming the cornerstone for a wide range of optical precision measurements. However, the wave function collapse in the single-photon SHE is unpredictable as spin collapse has inherent randomness governed by the Born rule. Here, nonlocal spin bunching and anti-bunching of polarization-entangled photon pairs called two-photon SHE is realized to predict and manipulate the wave function collapse, which is fundamentally different from the single-photon SHE. The two-photon SHE is sensitive to the relative phase among entangled photon pairs, enabling continuous control from nonlocal spin bunching to anti-bunching. Owing to the phase sensitivity of the two-photon SHE, an accurate and simple quantitative phase imaging scheme is realized. The two-photon SHE may pave the way for unveiling the wave function evolution in the SOI of light and manipulating spin-dependent photonic quantum effects.

Topics & Concepts

PhysicsRandomnessPhotonSpin (aerodynamics)PhotonicsPhase (matter)Quantum mechanicsWave function collapseFunction (biology)QuantumWave functionQuantum dotCondensed matter physicsRange (aeronautics)Spin waveSensitivity (control systems)Quantum electrodynamicsMacroscopic quantum phenomenaSimple (philosophy)Spin Hall effectQuantum optics and atomic interactionsQuantum Information and CryptographyOrbital Angular Momentum in Optics
Phase-sensitive wave function collapse in two-photon spin Hall effect | Litcius