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4. Entanglement Swapping with Photons Generated on Demand by a Quantum Dot. Basso Basset F; Rota MB; Schimpf C; Tedeschi D; Zeuner KD; Covre da Silva SF; Reindl M; Zwiller V; Jöns KD; Rastelli A; Trotta R Phys Rev Lett; 2019 Oct; 123(16):160501. PubMed ID: 31702339 [TBL] [Abstract][Full Text] [Related]
5. On-Demand Generation of Entangled Photon Pairs in the Telecom C-Band with InAs Quantum Dots. Zeuner KD; Jöns KD; Schweickert L; Reuterskiöld Hedlund C; Nuñez Lobato C; Lettner T; Wang K; Gyger S; Schöll E; Steinhauer S; Hammar M; Zwiller V ACS Photonics; 2021 Aug; 8(8):2337-2344. PubMed ID: 34476289 [TBL] [Abstract][Full Text] [Related]
6. Strain-Tunable GaAs Quantum Dot: A Nearly Dephasing-Free Source of Entangled Photon Pairs on Demand. Huber D; Reindl M; Covre da Silva SF; Schimpf C; Martín-Sánchez J; Huang H; Piredda G; Edlinger J; Rastelli A; Trotta R Phys Rev Lett; 2018 Jul; 121(3):033902. PubMed ID: 30085806 [TBL] [Abstract][Full Text] [Related]
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11. High yield and ultrafast sources of electrically triggered entangled-photon pairs based on strain-tunable quantum dots. Zhang J; Wildmann JS; Ding F; Trotta R; Huo Y; Zallo E; Huber D; Rastelli A; Schmidt OG Nat Commun; 2015 Dec; 6():10067. PubMed ID: 26621073 [TBL] [Abstract][Full Text] [Related]
12. Wavelength-tunable sources of entangled photons interfaced with atomic vapours. Trotta R; Martín-Sánchez J; Wildmann JS; Piredda G; Reindl M; Schimpf C; Zallo E; Stroj S; Edlinger J; Rastelli A Nat Commun; 2016 Jan; 7():10375. PubMed ID: 26815609 [TBL] [Abstract][Full Text] [Related]
13. On-Demand Semiconductor Source of Entangled Photons Which Simultaneously Has High Fidelity, Efficiency, and Indistinguishability. Wang H; Hu H; Chung TH; Qin J; Yang X; Li JP; Liu RZ; Zhong HS; He YM; Ding X; Deng YH; Dai Q; Huo YH; Höfling S; Lu CY; Pan JW Phys Rev Lett; 2019 Mar; 122(11):113602. PubMed ID: 30951338 [TBL] [Abstract][Full Text] [Related]
14. Solid-state ensemble of highly entangled photon sources at rubidium atomic transitions. Keil R; Zopf M; Chen Y; Höfer B; Zhang J; Ding F; Schmidt OG Nat Commun; 2017 May; 8():15501. PubMed ID: 28548092 [TBL] [Abstract][Full Text] [Related]
15. Two-photon interference in the telecom C-band after frequency conversion of photons from remote quantum emitters. Weber JH; Kambs B; Kettler J; Kern S; Maisch J; Vural H; Jetter M; Portalupi SL; Becher C; Michler P Nat Nanotechnol; 2019 Jan; 14(1):23-26. PubMed ID: 30348956 [TBL] [Abstract][Full Text] [Related]
16. High-Yield Fabrication of Entangled Photon Emitters for Hybrid Quantum Networking Using High-Temperature Droplet Epitaxy. Basso Basset F; Bietti S; Reindl M; Esposito L; Fedorov A; Huber D; Rastelli A; Bonera E; Trotta R; Sanguinetti S Nano Lett; 2018 Jan; 18(1):505-512. PubMed ID: 29239186 [TBL] [Abstract][Full Text] [Related]
17. Towards Scalable Entangled Photon Sources with Self-Assembled InAs/GaAs Quantum Dots. Wang J; Gong M; Guo GC; He L Phys Rev Lett; 2015 Aug; 115(6):067401. PubMed ID: 26296130 [TBL] [Abstract][Full Text] [Related]
18. Proposed Scheme to Generate Bright Entangled Photon Pairs by Application of a Quadrupole Field to a Single Quantum Dot. Zeeshan M; Sherlekar N; Ahmadi A; Williams RL; Reimer ME Phys Rev Lett; 2019 Jun; 122(22):227401. PubMed ID: 31283293 [TBL] [Abstract][Full Text] [Related]