Polarization entanglement-enabled quantum holography

By exploiting polarization entanglement between photons, quantum holography can circumvent the need for first-order coherence that is vital to classical holography. Holography is a cornerstone characterization and imaging technique that can be applied to the full electromagnetic spectrum, from X-rays to radio waves or even particles such as neutrons. The key property in all these holographic approaches is coherence, which is required to extract the phase information through interference with a reference beam. Without this, holography is not possible. Here we introduce a holographic imaging approach that operates on first-order incoherent and unpolarized beams, so that no phase information can be extracted from a classical interference measurement. Instead, the holographic information is encoded in the second-order coherence of entangled states of light. Using spatial-polarization hyper-entangled photon pairs, we remotely reconstruct phase images of complex objects. Information is encoded into the polarization degree of the entangled state, allowing us to image through dynamic phase disorder and even in the presence of strong classical noise, with enhanced spatial resolution compared with classical coherent holographic systems. Beyond imaging, quantum holography quantifies hyper-entanglement distributed over 10(4) modes via a spatially resolved Clauser-Horne-Shimony-Holt inequality measurement, with applications in quantum state characterization.

Automated summary

Holography is a fundamental characterization and imaging technique that relies on coherence, with classical holography requiring first-order coherence. Quantum holography, by utilizing polarization entanglement, allows for phase information extraction without the need for first-order coherence. This technique, using spatial-polarization hyper-entangled photon pairs, enables high-resolution imaging of complex objects even in the presence of dynamic phase disorder and strong classical noise.