Inverse design of high-dimensional quantum optical circuits in a complex medium

• Published in: Nature physics Vol. 20; no. 2; pp. 232 - 239
• Main Authors: Goel, Suraj, Leedumrongwatthanakun, Saroch, Valencia, Natalia Herrera, McCutcheon, Will, Tavakoli, Armin, Conti, Claudio, Pinkse, Pepijn W. H., Malik, Mehul
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 01.02.2024; Nature Publishing Group
• Subjects: 639/624/400/482; 639/766/483/481; Annan elektroteknik och elektronik; Atomic; Circuit design; Circuits; Classical and Continuum Physics; Complex media; Complex Systems; Complexity; Condensed Matter Physics; Data processing; Electrical Engineering, Electronic Engineering, Information Engineering; Elektroteknik och elektronik; Engineering and Technology; Fabrication; Gates (circuits); Inverse design; Mathematical and Computational Physics; Molecular; Optical and Plasma Physics; Other Electrical Engineering, Electronic Engineering, Information Engineering; Photonics; Physics; Physics and Astronomy; Quantum entanglement; Quantum phenomena; Teknik; Theoretical
• ISSN: 1745-2473; 1745-2481
• DOI: 10.1038/s41567-023-02319-6

Programmable optical circuits are an important tool in developing quantum technologies such as transceivers for quantum communication and integrated photonic chips for quantum information processing. Maintaining precise control over every individual component becomes challenging at large scales, leading to a reduction in the quality of operations performed. In parallel, minor imperfections in circuit fabrication are amplified in this regime, dramatically inhibiting their performance. Here we use inverse design techniques to embed optical circuits in the higher-dimensional space of a large, ambient mode mixer such as a commercial multimode fibre. This approach allows us to forgo control over each individual circuit element, and retain a high degree of programmability. We use our circuits as quantum gates to manipulate high-dimensional spatial-mode entanglement in up to seven dimensions. Their programmability allows us to turn a multimode fibre into a generalized multioutcome measurement device, allowing us to both transport and certify entanglement within the transmission channel. With the support of numerical simulations, we show that our method is a scalable approach to obtaining high circuit fidelity with a low circuit depth by harnessing the resource of a high-dimensional mode mixer. Light passing through complex media is subject to scattering processes that mix together different photonic modes. This complexity can be harnessed to implement quantum operations.