Quantum Network Research Publications

This paper presents experimental results from implementing quantum teleportation protocols over existing fiber optic infrastructure. The research demonstrates successful teleportation with 94% fidelity over distances of 30 km while sharing the optical fiber with conventional internet traffic. The paper details the experimental setup, measurement protocols, and techniques for mitigating decoherence effects in mixed quantum-classical networks.

This paper presents experimental evidence of non-classical temporal correlations in quantum network communications. Using a modified delayed-choice quantum eraser configuration across networked nodes, the researchers demonstrate correlations between measurement choices and outcomes that appear to violate classical causal ordering. The paper discusses implications for quantum routing algorithms and timing synchronization protocols in distributed quantum systems.

This paper presents a theoretical framework for understanding emergent information structures in multi-node quantum networks. Using a combination of quantum information theory and complex systems analysis, the authors model how entanglement patterns and quantum correlations give rise to coherent clustering phenomena. The paper includes extensive simulation results and introduces metrics for quantifying information cluster formation, stability, and information processing capacity.

This paper introduces novel metrics for quantifying information transfer efficiency in networks that combine quantum and classical infrastructure. The researchers develop a comprehensive framework that accounts for entanglement resources, classical communication bandwidth, and quantum state fidelity. The paper also presents optimization techniques that maximize transfer efficiency under realistic resource constraints, with experimental validation using a quantum network testbed.

This paper introduces novel routing algorithms for quantum networks that leverage information clustering phenomena. By identifying emergent entanglement structures and quantum correlation patterns, these algorithms dynamically optimize routing paths for quantum information transfer. Simulation results demonstrate significant improvements in transfer fidelity and resource utilization compared to conventional approaches. The paper was presented at QNet 2024, the International Conference on Quantum Networking.

This preprint explores how non-classical temporal correlations in quantum networks can be leveraged for enhanced clock synchronization protocols. The authors demonstrate that entanglement-based synchronization can achieve precision beyond classical limits, especially in networks with varying latency and jitter. The paper presents both theoretical foundations and preliminary experimental results from a quantum network testbed.