Nick Peters

Nicholas A Peters

Section Head & Distinguished Research and Development Staff in The Quantum Information Science Section

Contact

865.576.3386 | PETERSNA@ORNL.GOV

All Publications

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...

Generation and characterization of ultrabroadband polarization–frequency hyperentangled photons...

Two-mode squeezing over deployed fiber coexisting with conventional communications

Coexistent Quantum Channel Characterization Using Spectrally Resolved Bayesian Quantum Process Tomography

Paving the Way for Satellite Quantum Communications

Authentication of smart grid communications using quantum key distribution

Reconfigurable Quantum Local Area Network Over Deployed Fiber

Trusted Node QKD at an Electrical Utility...

Testbed and Experiments for Quantum-Conventional Networking

Polarization-agnostic continuous-variable quantum key distribution...

Quantum nonlocal modulation cancelation with distributed clocks

Entanglement Capacity Estimates and Throughput Measurements of Quantum Channels

Procrustean entanglement concentration for quantum-classical coexistence

Building a controlled-NOT gate between polarization and frequency...

Modeling and Validation of Offset Cancellation for Hybrid Photonic-Electronic Transimpedance Amplifier Using All-Electronic C...

Polarization–frequency hyperentangled photons: generation, characterization, and manipulation

Quantum digital signatures over entanglement-based deployed campus network

Quantum Key Distribution for Critical Infrastructures: Towards Cyber-Physical Security for Hydropower and Dams

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

Continuous-variable quantum key distribution with true local oscillator