Posters
Poster boards will fit posters prepared in a vertical A0 format (width: 84 cm, height: 119 cm).
| Michele | Amoretti | University of Parma | Distributed Functional Monitoring in Quantum Networks |
| Matthias | Bock | Saarland University |
Ion-Telecom Photon Entanglement via Polarization-Preserving Quantum Frequency Conversion
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| Johannes | Borregaard | University of Copenhagen | Quantum enhanced telescopic arrays |
| Manuel | Brekenfeld | Max Planck Institute of Quantum Optics | Proposal for a telecom quantum repeater with single atoms in optical cavities |
| Gianni | Buser | University of Basel | Simple atomic quantum memory suitable for semiconductor quantum dot single photons |
| Kevin | Cox | US Army Research Laboratory | Quantum Technologies Using Rydberg Atoms in an Optical Cavity |
| Axel | Dahlberg | TU Delft | Routing entanglement in a quantum network, using graph states |
| Severin | Daiss | Max-Planck-Institut für Quantenoptik | Entangling Two Matter Qubits Using Cavity QED |
| Sumanta | Das | Niels Bohr Institute | Interfacing optical photons with superconducting qubits for future quantum networks |
| Aymeric | Delteil | Institute of Quantum Electronics, ETH Zurich |
Realization of a Cascaded Quantum System: Heralded Absorption of a Single Photon Qubit by a Single-Electron Charged Quantum Dot
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| Juergen | Eschner | Universität des Saarlandes, Experimentalphysik | Programmable single-atom to single-photon quantum interface |
| Elizabeth | Goldschmidt | US Army Research Laboratory | Toward quantum memory in stoichiometric rare-earth solids |
| Kenneth | Goodenough | QuTech, Delft University of Technology | Realistic parameter regimes for a single quantum repeater node |
| Timo | Holz | Heinrich-Heine University, Theoretical Physics III | Device-independent Secret Key Rates for Quantum Repeater Setups |
| Peter | Humphreys | TU Delft | Towards quantum networks using diamond spins |
| Pierre | Jobez |
University of Innsbruck |
Towards the strong coupling regime for a trapped ion in an optical fiber cavity |
| Sumeet | Khatri | Louisiana State University | Long-distance communication with memoryless quantum repeaters |
| Hideo | Kosaka | Yokohama National University | Quantum repeater based on absorption and emission in diamond |
| Paul | Kunz | US Army Research Laboratory |
Quantum memory using high cooperativity regime with Rydberg ensemble and ex-vacuo cavity
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| Viacheslav | Kuzmin | Institute for Quantum Optics and Quantum Information (IQOQI) | 2D quantum repeaters |
| Stefan | Langenfeld | Max Planck Institute of Quantum Optics | Memory for photonic polarization qubits with long coherence time |
| Nikolai | Lauk | University of Calgary | Rare-earth ions based quantum repeater at telecom wavelength |
| Lin | Li | Max-Planck Institute of Quantum Optics | A photon-mediated quantum gate between two neutral atoms in an optical cavity |
| Michael | Zwerger | Universität Innsbruck | Long-range big quantum-data transmission |
| Xiao | Liu | University of Science and Technology of China (USTC) | Semihierarchical quantum repeaters based on moderate lifetime quantum memories | |
| Takaaki | Matsuo | Keio University |
Analysis of Measurement-based Quantum Network Coding Protocol over Repeater Networks under Noisy Conditions
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| Roberto | Mottola | Universität Basel | Atomic quantum memory in the Paschen-Back regime | |
| sreraman | Muralidharan | Yale University | Third generation quantum repeaters with Quantum Reed-Solomon codes | |
| Shota | Nagayama | Eotvos Lorand University | Analysis of scalable quantum router architecture with code interoperability | |
| Dominik | Niemietz | Max Planck Institute of Quantum Optics | Towards single neutral atoms in crossed fiber cavities | |
| Takafumi | Oka | Keio University | A Classical Network Protocol to Support Distributed Quantum State Tomography | |
| Alexander | Pirker | University of Innsbruck | Confidentiality of the hashing protocol and applications to the quantum repeater | |
| Andreas | Reiserer | MPI of Quantum Optics | Cavity-enhanced coupling of Erbium spins to NIR photons | |
| Jeremy | Ribeiro | Qutech, TU Delft | A Device Independent protocol for Conference Key Agreement | |
| Filip | Rozpedek | QuTech, TU Delft | Multiplexed entanglement generation and quantum repeaters using multi-qubit nodes | |
| Takahiko | Satoh | Keio University | The Network Impact of Hijacking a Quantum Repeater. | |
| Tim | Schröder | Niels Bohr Institute, University of Copenhagen | Towards on-chip entangled photon generation for quantum communication applications | |
| Yuhei | Sekiguchi | Yokohama National University | All-optical control of a single spin memory in diamond | |
| Oliver | Slattery | NIST Information Technology Laboratory | Single Photon Source and Cesium Based Quantum Memory for Quantum Repeater | |
| Sergei | Slussarenko | Centre for Quantum Dynamics, Griffith University | Heralded quantum steering over a high-loss quantum channel | |
| Neal | Solmeyer | Army Research Laboratory | Progress towards a neutral atom quantum repeater | |
| Mohammad Amin | Taherkhani | Shahid Beheshti University |
Security evaluation of practical quantum aided Byzantine agreement on quantum repeater networks
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| Markus | Teller | University of Innsbruck | Single-ion addressing in a three-node quantum network | |
| Rodney | Van Meter | Keio University | 2.5G Quantum Repeaters | |
| Julius | Wallnöfer | Institute for Theoretical Physics, University of Innsbruck | Multipartite Quantum Hashing for Quantum Networks | |
| Tianshu | Yang | University Of Science And Technology Of China |
A multiplexed solid-state quantum memory operating in temporal, spatial and frequency domain
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| Zong-Quan | Zhou | CAS Key lab of quantum information University of Science and Technology of China | Long-term storage of radiofrequency photons in solids |