ScholarlyArticle: "Telecom-wavelength quantum teleportation using frequency-converted photons from remote quantum dots" (2025) https://www.nature.com/articles/s41467-025-65912-8 :
> Abstract: [...] Here, we realize full-photonic quantum teleportation employing semiconductor quantum dots, which can fulfill all the aforementioned requirements. Two remote GaAs quantum dots, emitting in the near-infrared, are used: one as an entangled-photon pair source and the other as a single-photon source. During the experiment, the single photon is prepared in conjugate polarization states and interfaced with the biexciton emission of the entangled pair employing a polarization-selective Bell state measurement. This process teleports the respective polarization state onto the exciton emission of the entangled pair. The frequency mismatch between the triggered sources is erased using two polarization-preserving quantum frequency converters, enabling remote two-photon interference at telecommunication wavelengths, yielding a visibility of 30(1)%. A post-selected teleportation fidelity up to 0.721(33), significantly above the classical limit, demonstrates successful quantum teleportation between light from distinct sources. These results mark an important development for semiconductor-based quantum light sources.
NewsArticle; "Physicists Teleport Light Between Tiny Crystals, Pushing Quantum Internet Closer" https://scienceblog.com/physicists-teleport-light-between-ti...
NewsArticle: "Quantum teleportation between photons from two distant light sources achieved" https://phys.org/news/2025-11-quantum-teleportation-photons-... :
> In the Stuttgart experiment, the quantum dots were separated only by an optical fiber of about 10 m length. "But we are working on achieving considerably greater distances," says Strobel.
> In earlier work, the team had shown that the entanglement of the quantum dot photons remains intact even after a 36-kilometer transmission through the city center of Stuttgart. Another aim is to increase the current success rate of teleportation, which currently stands at just over 70%. Fluctuations in the quantum dot still lead to slight differences in the photons.
> "We want to reduce this by advancing semiconductor fabrication techniques," says Strobel.
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