Free-space quantum information platform on a chip

TL;DR

This paper introduces a scalable, integrated quantum platform using a quantum phased array for free-space quantum communication, sensing, and computing, demonstrating reconfigurable links, quantum imaging, and entanglement generation.

Contribution

It presents the first demonstration of a quantum phased array with integrated nanophotonic antennas enabling reconfigurable free-space quantum links and processing.

Findings

32-channel array of quantum coherent receivers with high shot noise clearance

Successful 32-pixel imaging of squeezed light for quantum sensing

Reconfigurable free-space links demonstrated for quantum communication

Abstract

Emerging technologies that employ quantum physics offer fundamental enhancements in information processing tasks, including sensing, communications, and computing. Here, we introduce the quantum phased array, which generalizes the operating principles of phased arrays and wavefront engineering to quantum fields, and report the first quantum phased array technology demonstration. An integrated photonic-electronic system is used to manipulate free-space quantum information to establish reconfigurable wireless quantum links in a standalone, compact form factor. Such a robust, scalable, and integrated quantum platform can enable broad deployment of quantum technologies with high connectivity, potentially expanding their use cases to real-world applications. We report the first, to our knowledge, free-space-to-chip interface for quantum links, enabled by 32 metamaterial antennas with more than 500,000 sub-wavelength engineered nanophotonic elements over a 550 x 550 $\mathrm{\mu m}^2$ physical aperture. We implement a 32-channel array of quantum coherent receivers with 30.3 dB shot noise clearance and 90.2 dB common-mode rejection ratio that downconverts the quantum optical information via homodyne detection and processes it coherently in the radio-frequency domain. With our platform, we demonstrate 32-pixel imaging of squeezed light for quantum sensing, reconfigurable free-space links for quantum communications, and proof-of-concept entanglement generation for measurement-based quantum computing. This approach offers targeted, real-time, dynamically-adjustable free-space capabilities to integrated quantum systems that can enable wireless quantum technologies.