Quantum Interference between Transverse Spatial Waveguide Modes

TL;DR

This paper demonstrates a scalable quantum photonic platform using transverse spatial modes in waveguides, enabling higher-dimensional quantum information processing with integrated mode multiplexers and beamsplitters.

Contribution

Introduction of a multimode waveguide platform utilizing transverse spatial modes for scalable quantum photonic circuits with tunable interference and NOON state generation.

Findings

Demonstrated tunable quantum interference between spatial modes

Implemented cascaded structures for NOON state interferometry

Showed potential for scalable higher-dimensional quantum systems

Abstract

Integrated quantum optics has drastically reduced the size of table-top optical experiments to the chip-scale, allowing for demonstrations of large-scale quantum information processing and quantum simulation. However, despite these advances, practical implementations of quantum photonic circuits remain limited because they consist of large networks of waveguide interferometers that path encode information which do not easily scale. Increasing the dimensionality of current quantum systems using higher degrees of freedom such as transverse spatial field distribution, polarization, time, and frequency to encode more information per carrier will enable scalability by simplifying quantum computational architectures, increasing security and noise tolerance in quantum communication channels, and simulating richer quantum phenomena. Here we demonstrate a scalable platform for photonic quantum information processing using waveguide quantum circuit building blocks based on the transverse spatial mode degree of freedom: mode multiplexers and mode beamsplitters. A multimode waveguide is inherently a densely packed system of spatial and polarization modes that can be coupled by perturbations to the waveguide. We design a multimode waveguide consisting of three spatial modes (per polarization) and a nanoscale grating beamsplitter to show tunable quantum interference between pairs of photons in different transverse spatial modes. We also cascade these structures and demonstrate NOON state interferometry within a multimode waveguide. These devices have potential to perform transformations on more modes and be integrated with existing architectures, providing a scalable path to higher-dimensional Hilbert spaces and entanglement.