Abstract
Hybrid encodings, where multiple degrees of freedom are used to encode quantum information, can increase the size of the Hilbert space with minimal increase to hardware requirements. We show a reprogrammable integrated photonic device, with multimodal components designed to allow for control over the transverse electric modes. We use this device to generate qudit states entangled in the path and transverse electric mode degrees of freedom. We generate and verify a hyperentangled state with a fidelity of ℱHE =67.3±0.2
% and a GHZ4-style state with a fidelity of ℱGHZ4=85.2±0.4%. We use our hyperentangled state in a single-copy entanglement distillation protocol, resulting in an average 9.1% increase in the fidelity of the distilled Bell state for up to a 50% probability of bit flip error. By utilising degrees of freedom which are readily compatible with integrated photonics, our work highlights how this hybrid encoding demonstrates a first step in using the transverse electric mode to reduce the footprint of integrated quantum photonic experiments.
% and a GHZ4-style state with a fidelity of ℱGHZ4=85.2±0.4%. We use our hyperentangled state in a single-copy entanglement distillation protocol, resulting in an average 9.1% increase in the fidelity of the distilled Bell state for up to a 50% probability of bit flip error. By utilising degrees of freedom which are readily compatible with integrated photonics, our work highlights how this hybrid encoding demonstrates a first step in using the transverse electric mode to reduce the footprint of integrated quantum photonic experiments.
| Original language | English |
|---|---|
| Publisher | arXiv.org |
| Number of pages | 14 |
| DOIs | |
| Publication status | Published - 17 Oct 2025 |
Keywords
- quant-ph