Your search keyword '"Joaquín Medina Dueñas"' showing total 2 results

1. Transport of non-classical light mediated by topological domain walls in a SSH photonic lattice

Author

Gabriel O’Ryan Pérez, Joaquín Medina Dueñas, Diego Guzmán-Silva, Luis E. F. Foa Torres, and Carla Hermann-Avigliano

Subjects

Medicine, Science

Abstract

Abstract Advancements in photonics technologies have significantly enhanced their capability to facilitate experiments involving quantum light, even at room temperature. Nevertheless, fully integrating photonic chips that include quantum light sources, effective manipulation and transport of light minimizing losses, and appropriate detection systems remains an ongoing challenge. Topological photonic systems have emerged as promising platforms to protect quantum light properties during propagation, beyond merely preserving light intensity. In this work, we delve into the dynamics of non-classical light traversing a Su-Schrieffer-Heeger photonic lattice with topological domain walls. Our focus centers on how topology influences the quantum properties of light as it moves across the array. By precisely adjusting the spacing between waveguides, we achieve dynamic repositioning and interaction of domain walls, facilitating effective beam-splitting operations. Our findings demonstrate high-fidelity transport of non-classical light across the lattice, replicating known results that are now safeguarded by the topology of the system. This protection is especially beneficial for quantum communication protocols with continuous variable states. Our study enhances the understanding of light dynamics in topological photonic systems and paves the way for high-fidelity, topology-protected quantum communication.

Published

2024

2. Quadrature protection of squeezed states in a one-dimensional photonic topological insulator

Author

Joaquin Medina Dueñas, Gabriel O'Ryan Pérez, Carla Hermann-Avigliano, and Luis E. F. Foa Torres

Subjects

Physics, QC1-999

Abstract

What is the role of topology in the propagation of quantum light in photonic lattices? We address this question by studying the propagation of squeezed states in a topological one-dimensional waveguide array, benchmarking our results with those for a topologically trivial localized state, and studying their robustness against disorder. Specifically, we study photon statistics, one-mode and two-mode squeezing, and entanglement generation when the localized state is excited with squeezed light. These quantum properties inherit the shape of the localized state but, more interestingly, and unlike in the topologically trivial case, we find that propagation of squeezed light in a topologically protected state robustly preserves the phase of the squeezed quadrature as the system evolves. We show how this latter topological advantage can be harnessed for quantum information protocols.

Published

2021