{"@type": "dcat:Dataset", "accessLevel": "public", "accrualPeriodicity": "irregular", "bureauCode": ["006:55"], "contactPoint": {"fn": "Tasshi Dennis", "hasEmail": "mailto:tasshi.dennis@nist.gov"}, "description": "Data presented is part of abstract and poster titled \"Entangling Superconducting Qubits over Optical Fiber ? Towards Optimization and Implementation\" presented at \"IEEE International Conference on Quantum Computing and Engineering - QCE22\". Data includes a demonstration of squeezed light generation as the twin beam difference current relative to shot noise and a numerical simulation of the performance of 4 quantum network topologies.", "distribution": [{"description": "Explanation for datasets provided as spreadsheet comma-separated-values.", "downloadURL": "https://data.nist.gov/od/ds/mds2-2756/2756_README.txt", "format": "English text", "mediaType": "text/plain", "title": "Remove"}, {"downloadURL": "https://data.nist.gov/od/ds/mds2-2756/2756_README.txt", "mediaType": "text/plain", "title": "Readme File"}, {"downloadURL": "https://data.nist.gov/od/ds/mds2-2756/2756_README.txt", "mediaType": "text/plain", "title": "Remove"}, {"downloadURL": "https://data.nist.gov/od/ds/mds2-2756/firstSqueezingSpectrumShotNoiseAndSubShotNoise.csv", "mediaType": "text/csv", "title": "Measured Squeezing Spectrum"}, {"downloadURL": "https://data.nist.gov/od/ds/mds2-2756/networkSimulation.csv", "mediaType": "text/csv", "title": "Simulated Network Topology Thresholds"}], "identifier": "ark:/88434/mds2-2756", "issued": "2023-01-19", "keyword": ["entanglement", "quantum computing", "quantum networks", "squeezed state", "superconducting", "transduction"], "landingPage": "https://data.nist.gov/od/id/mds2-2756", "language": ["en"], "license": "https://www.nist.gov/open/license", "modified": "2022-08-15 00:00:00", "programCode": ["006:045"], "publisher": {"@type": "org:Organization", "name": "National Institute of Standards and Technology"}, "theme": ["Advanced Communications:Quantum communications"], "title": "Entangling Superconducting Qubits over Optical Fiber - Towards Optimization and Implementation"}