An NEGF-based framework formulates impact ionization as a multi-particle self-energy to enable energy-resolved, non-perturbative modeling of carrier multiplication in nanoscale avalanche devices for quantum applications.
Quantum cryptography based on bell’s theorem
3 Pith papers cite this work. Polarity classification is still indexing.
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Pith papers citing it
fields
quant-ph 3years
2026 3verdicts
UNVERDICTED 3representative citing papers
Extends the SeQUeNCe simulator with Jones-calculus components and multi-section fiber models to enable validated, hardware-parameterized predictions of entanglement distribution in polarization-encoded quantum networks.
Geometric phase control compensates phases in Bell states for QKD, achieving over 95% fidelity and QBER below 11% in a proof-of-concept experiment.
citing papers explorer
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NEGF Modeling of Impact Ionization in Semiconductor Avalanche Photodiodes for Quantum Networking
An NEGF-based framework formulates impact ionization as a multi-particle self-energy to enable energy-resolved, non-perturbative modeling of carrier multiplication in nanoscale avalanche devices for quantum applications.
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Physics-Informed Discrete-Event Simulation of Polarization-Encoded Quantum Networks
Extends the SeQUeNCe simulator with Jones-calculus components and multi-section fiber models to enable validated, hardware-parameterized predictions of entanglement distribution in polarization-encoded quantum networks.
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Geometric phase-assisted simple phase compensation enabling quantum key distribution using phase-shifted Bell states
Geometric phase control compensates phases in Bell states for QKD, achieving over 95% fidelity and QBER below 11% in a proof-of-concept experiment.