Joseph Chapman Research Scientist in Quantum Communications Contact CHAPMANJC@ORNL.GOV All Publications Testbed and Experiments for Quantum-Conventional Networking Continuous automatic polarization channel stabilization from heterodyne detection of coexisting dim reference signals Entanglement Capacity Estimates and Throughput Measurements of Quantum Channels... Quantum digital signatures over entanglement-based deployed campus network Entanglement-based quantum digital signatures over a deployed campus network Two-mode squeezing over deployed fiber coexisting with conventional communications Two-mode squeezing over deployed fiber coexisting with conventional communications Throughput Measurements and Capacity Estimates for Quantum Connections... Coexistent Quantum Channel Characterization Using Spectrally Resolved Bayesian Quantum Process Tomography Coexistent quantum channel characterization using quantum process tomography with spectrally resolved detection... Characterizing non-polarization-maintaining highly nonlinear fiber toward squeezed-light generation Paving the Way for Satellite Quantum Communications Entanglement Verification of Hyperentangled Photon Pairs Hyperentangled Time-Bin and Polarization Quantum Key Distribution Heterodyne spectrometer sensitivity limit for quantum networking Sensitivity Limitation of an Optical Heterodyne Spectrometer Bayesian Optical Heterodyne Tomography Quantum Networking and Communications at Oak Ridge National Laboratory Bayesian homodyne and heterodyne tomography Lessons Learned on the Interface Between Quantum and Conventional Networking Key Links Organizations Computing and Computational Sciences Directorate Computational Sciences and Engineering Division Quantum Information Science Section Quantum Communications and Networking Group
News EPB, ORNL announce plans for research collaborative focused on energy resilience, quantum technology
