1Center for Hybrid Quantum Networks (Hy-Q), The Niels Bohr Institute, University of Copenhagen, Blegdamsvej 17, DK-2100 Copenhagen Ø, Denmark
2NNF Quantum Computing Programme, Niels Bohr Institute, University of Copenhagen, Denmark.
រកក្រដាសនេះគួរឱ្យចាប់អារម្មណ៍ឬចង់ពិភាក្សា? ខ្ជះខ្ជាយឬទុកមតិយោបល់លើ SciRate.
អរូបី
We develop an architecture for measurement-based quantum computing using photonic quantum emitters. The architecture exploits spin-photon entanglement as resource states and standard Bell measurements of photons for fusing them into a large spin-qubit cluster state. The scheme is tailored to emitters with limited memory capabilities since it only uses an initial non-adaptive (ballistic) fusion process to construct a fully percolated graph state of multiple emitters. By exploring various geometrical constructions for fusing entangled photons from deterministic emitters, we improve the photon loss tolerance significantly compared to similar all-photonic schemes.
►ទិន្នន័យគន្ថនិទ្ទេស
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[90] Sam Morley-Short, Mercedes Gimeno-Segovia, Terry Rudolph, and Hugo Cable. “Loss-tolerant teleportation on large stabilizer states”. Quantum Science and Technology 4, 025014 (2019).
https://doi.org/10.1088/2058-9565/aaf6c4
បានលើកឡើងដោយ
[1] Grégoire de Gliniasty, Paul Hilaire, Pierre-Emmanuel Emeriau, Stephen C. Wein, Alexia Salavrakos, and Shane Mansfield, “A Spin-Optical Quantum Computing Architecture”, arXiv: 2311.05605 ។, (2023).
[2] Yijian Meng, Carlos F. D. Faurby, Ming Lai Chan, Patrik I. Sund, Zhe Liu, Ying Wang, Nikolai Bart, Andreas D. Wieck, Arne Ludwig, Leonardo Midolo, Anders S. Sørensen, Stefano Paesani, and Peter Lodahl, “Photonic fusion of entangled resource states from a quantum emitter”, arXiv: 2312.09070 ។, (2023).
[3] Matthias C. Löbl, Stefano Paesani, and Anders S. Sørensen, “Efficient algorithms for simulating percolation in photonic fusion networks”, arXiv: 2312.04639 ។, (2023).
[4] Philip Thomas, Leonardo Ruscio, Olivier Morin, and Gerhard Rempe, “Fusion of deterministically generated photonic graph states”, arXiv: 2403.11950 ។, (2024).
ការដកស្រង់ខាងលើគឺមកពី SAO / NASA ADS (បានធ្វើបច្ចុប្បន្នភាពចុងក្រោយដោយជោគជ័យ ២០២០-០១-២៣ ១០:២៥:៣៦) ។ បញ្ជីនេះអាចមិនពេញលេញដូចដែលអ្នកបោះពុម្ពផ្សាយទាំងអស់មិនផ្តល់នូវទិន្នន័យដកស្រង់ដែលសមរម្យនិងពេញលេញ។
មិនអាចទៅយក គេហទំព័រ crossref ដកស្រង់ដោយទិន្នន័យ ក្នុងអំឡុងពេលការប៉ុនប៉ងចុងក្រោយ ២០២០-០៦-០៤ ១២:៤៨:២១: មិនអាចទាញយកទិន្នន័យដែលបានដកស្រង់បានសម្រាប់ ១០.២២៣៣១ / q-២០២០-០៦-០៤-២៧៩ ពីក្រុមហ៊ុន Crossref ។ នេះជារឿងធម្មតាប្រសិនបើ DOI ត្រូវបានចុះបញ្ជីថ្មីៗនេះ។
ក្រដាសនេះត្រូវបានបោះពុម្ភផ្សាយជាអក្សរថាមនៅក្រោមឯកសារ ភាពច្នៃប្រឌិតនៃភាពជាអ្នកដឹកនាំ ៤.០ អន្តរជាតិ (ស៊ីស៊ី ៤.០) អាជ្ញាប័ណ្ណ។ ការរក្សាសិទ្ធិនៅតែមានជាមួយអ្នករក្សាសិទ្ធិដើមដូចជាអ្នកនិពន្ធឬស្ថាប័នរបស់ពួកគេ។
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- ប្រភព: https://quantum-journal.org/papers/q-2024-03-28-1302/
