Nicholas A Peters Section Head & Distinguished Research and Development Staff in The Quantum Information Science Section Contact petersna@ornl.gov | 865.576.3386 All Publications Nobel-winning quantum weirdness undergirds an emerging high-tech industry, promising better ways of encrypting communications and imaging your body Reconfigurable Quantum Local Area Network Over Deployed Fiber... Effects of a nuclear disturbed environment on a quantum free space optical link... Trusted Node QKD at an Electrical Utility... Building a controlled-NOT gate between polarization and frequency Modeling and Validation of Offset Cancellation for Hybrid Photonic-Electronic Transimpedance Amplifier Using All-Electronic Circuits Polarization–frequency hyperentangled photons: generation, characterization, and manipulation Procrustean entanglement concentration in quantum-classical networking Entanglement-based quantum digital signatures over a deployed campus network... Field test of continuous-variable quantum key distribution with a true local oscillator Quantum Key Distribution for Critical Infrastructures: Towards Cyber-Physical Security for Hydropower and Dams Generation and characterization of ultrabroadband polarization–frequency hyperentangled photons Procrustean entanglement concentration in dense wavelength-division multiplexing Characterization of Quantum Frequency Processors... Tomography of ultrabroadband polarization-frequency hyperentangled photons Two-mode squeezing over deployed fiber coexisting with conventional communications Two-mode squeezing over deployed fiber coexisting with conventional communications Continuous-variable quantum key distribution with true local oscillator Space-based quantum networking in the presence of a nuclear disturbed environment Polarization-entangled source for flex-grid C+L-band quantum networks Throughput Measurements and Capacity Estimates for Quantum Connections Coexistent Quantum Channel Characterization Using Spectrally Resolved Bayesian Quantum Process Tomography Characterizing non-polarization-maintaining highly nonlinear fiber toward squeezed-light generation Coexistent quantum channel characterization using quantum process tomography with spectrally resolved detection Effects of a nuclear-disturbed environment on electromagnetic wave propagation through the atmosphere... Pagination Current page 1 Page 2 Page 3 … Next page ›› Last page Last » Key Links Google Scholar ORCID LinkedIn IMPACT@ORNL Organizations Computing and Computational Sciences Directorate Computational Sciences and Engineering Division Quantum Information Science Section