Non-Markovianity in High-Dimensional Open Quantum Systems using Next-generation Multicore Optical Fibers

With the advent of quantum technology, the interest in communication tasks assisted by quantum systems has increased both in academia and industry. Nonetheless, the transmission of a quantum state in real-world scenarios is bounded by environmental noise, so that the quantum channel is an open quantum system. In this work, we study a high dimensional non-Markovian open quantum system in a multi-core optical fiber by characterizing the environmental interaction as quantum operations, which here correspond to phase flips between pairs of computational basis states. The experimental platform is currently state-of-the-art for space division multiplexing optical fiber communication, which can serve as a robust channel for high-dimensional quantum communication. To test the channel, we perform a quantum communication task in the prepare-and-measure scenario. The non-Markovian nature of the system is demonstrated by implementing a Quantum Vault protocol. A better understanding of the phase noise in multi-core fibers could improve the stability and quality of several real-world communication protocols since they are a prime candidate to increase the telecom data transmission rate worldwide.