Anyonic two-photon statistics with a semiconductor chip

• URL: http://arxiv.org/abs/2106.16045v1
• Date: Wed, 30 Jun 2021 13:19:15 GMT
• Title: Anyonic two-photon statistics with a semiconductor chip
• Authors: S. Francesconi, A. Raymond, N. Fabre, A. Lema^itre, M. I. Amanti, P. Milman, F. Baboux, S. Ducci
• Abstract summary: We use parametric down-conversion in an integrated semiconductor chip to generate biphoton states simulating anyonic particle statistics. Our scheme exploits the frequency entanglement of the photon pairs, which is directly controlled through the spatial shaping of the pump beam. These results, demonstrated at room temperature and telecom wavelength on a chip-integrated platform, pave the way to the practical implementation of quantum simulation tasks with tailored particle statistics.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Anyons, particles displaying a fractional exchange statistics intermediate between bosons and fermions, play a central role in the fractional quantum Hall effect and various spin lattice models, and have been proposed for topological quantum computing schemes due to their resilience to noise. Here we use parametric down-conversion in an integrated semiconductor chip to generate biphoton states simulating anyonic particle statistics, in a reconfigurable manner. Our scheme exploits the frequency entanglement of the photon pairs, which is directly controlled through the spatial shaping of the pump beam. These results, demonstrated at room temperature and telecom wavelength on a chip-integrated platform, pave the way to the practical implementation of quantum simulation tasks with tailored particle statistics.

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