Data provided by National Institute of Standards and Technology
Data presented is part of the journal manuscript "Optically Distributing Remote Two-node Microwave Entanglement using Doubly Parametric Quantum Transducers." Data includes graphical plots generated from numerical models and computations for various network topologies which illustrate their thresholds for achieving quantum information transfer.
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Updated: 2024-02-22
Metadata Last Updated:
2022-11-07 00:00:00
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| Title | Optically Distributing Remote Two-node Microwave Entanglement using Doubly Parametric Quantum Transducers |
|---|---|
| Description | Data presented is part of the journal manuscript "Optically Distributing Remote Two-node Microwave Entanglement using Doubly Parametric Quantum Transducers." Data includes graphical plots generated from numerical models and computations for various network topologies which illustrate their thresholds for achieving quantum information transfer. |
| Modified | 2022-11-07 00:00:00 |
| Publisher Name | National Institute of Standards and Technology |
| Contact | mailto:[email protected] |
| Keywords | quantum networks , quantum computing , superconducting , transduction , squeezed state , entanglement |
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"fn": "Tasshi Dennis"
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"title": "Optically Distributing Remote Two-node Microwave Entanglement using Doubly Parametric Quantum Transducers",
"description": "Data presented is part of the journal manuscript \"Optically Distributing Remote Two-node Microwave Entanglement using Doubly Parametric Quantum Transducers.\" Data includes graphical plots generated from numerical models and computations for various network topologies which illustrate their thresholds for achieving quantum information transfer.",
"language": [
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"distribution": [
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"description": "Modeled and computed network entanglement thresholds for preserving quantum information for the eight network topologies illustrated in Table 1 as a function of optical cooperativity where microwave cooperativity is small. Quantum information is preserved above the curves and separable below. In the spreadsheet, column A is unitless optical cooperativity for the horizontal axis, and for the vertical axis the thermal occupation for the topologies of Extrinsic Optical Downconversion (column B), Extrinsic Microwave Downconversion (column C), Intrinsic Optical Downconversion (column D), Intrinsic Microwave Downconversion (column E), Extrinsic Optical Swapping (column F), Extrinsic Microwave Swapping (column G), Intrinsic Optical Swapping (column H), Intrinsic Microwave Swapping (column I).",
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"description": "Modeled and computed network entanglement thresholds for preserving quantum information for the eight network topologies illustrated in Table 1 as a function of optical cooperativity where microwave cooperativity is large. Quantum information is preserved above the curves and separable below. In the spreadsheet, column A is unitless optical cooperativity for the horizontal axis, and for the vertical axis the thermal occupation for the topologies of Extrinsic Optical Downconversion (column B), Extrinsic Microwave Downconversion (column C), Intrinsic Optical Downconversion (column D), Intrinsic Microwave Downconversion (column E), Extrinsic Optical Swapping (column F), Extrinsic Microwave Swapping (column G), Intrinsic Optical Swapping (column H), Intrinsic Microwave Swapping (column I).",
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{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-2844\/N_vs_Ea_opt.csv",
"description": "Modeled and computed network entanglement thresholds for preserving quantum information for the eight network topologies illustrated in Table 1 as a function of optical device loss. Quantum information is preserved above the curves and separable below. In the spreadsheet, column A is unitless optical device transmissivity (equivalent to loss) for the horizontal axis, and for the vertical axis the normalized thermal occupation for the topologies of Extrinsic Optical Downconversion (column B), Extrinsic Microwave Downconversion (column C), Intrinsic Optical Downconversion (column D), Intrinsic Microwave Downconversion (column E), Extrinsic Optical Swapping (column F), Extrinsic Microwave Swapping (column G), Intrinsic Optical Swapping (column H), Intrinsic Microwave Swapping (column I).",
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{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-2844\/En_vs_Et_realistic_device.csv",
"description": "Modeled and computed logarithmic negativity of the final microwave-microwave state generated by each network topology considered, using recently reported electro-optic-mechanical transducer parameters plotted as a function of optical loss external to the transducers. In the spreadsheet, column A is unitless optical transmissivity (equivalent to loss) for the horizontal axis, and for the unitless vertical axis column B is Extrinsic Optical Downconversion with 10 dB squeezing, column C is Extrinsic Optical Downconversion with 3 dB squeezing, column D is Extrinsic Optical Swapping with 10 dB squeezing, column E is Intrinsic Microwave Downconversion, and column F is Intrinsic Microwave Swapping.",
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{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-2844\/En_vs_Et_asymmetric.csv",
"description": "Modeled and computed logarithmic negativity of the final microwave-microwave state generated by each network topology considered, using recently reported electro-optic-mechanical transducer parameters plotted as a function of optical loss external to the transducers where the optical loss may be distributed asymmetrically within the network links. In the spreadsheet, column A is unitless optical transmissivity (equivalent to loss) for the horizontal axis, and for the unitless vertical axis column B is extrinsic optical symmetric, column C is intrinsic microwave symmetric, column D is intrinsic microwave asymmetric, column intrinsic microwave plus extrinsic optical asymmetric.",
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"modified": "2022-11-07 00:00:00",
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"name": "National Institute of Standards and Technology"
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"theme": [
"Advanced Communications:Quantum communications",
"Physics:Atomic, molecular, and quantum",
"Physics:Quantum information science",
"Physics:Optical physics"
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"keyword": [
"quantum networks",
"quantum computing",
"superconducting",
"transduction",
"squeezed state",
"entanglement"
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}
