A fully packaged multi-channel cryogenic module for optical quantum memories

• URL: http://arxiv.org/abs/2302.12919v2
• Date: Wed, 17 May 2023 15:43:48 GMT
• Title: A fully packaged multi-channel cryogenic module for optical quantum memories
• Authors: David J. Starling, Katia Shtyrkova, Ian Christen, Ryan Murphy, Linsen Li, Kevin C. Chen, Dave Kharas, Xingyu Zhang, John Cummings, W. John Nowak, Eric Bersin, Robert J. Niffenegger, Madison Sutula, Dirk Englund, Scott Hamilton, P. Benjamin Dixon
• Abstract summary: We report on a cryogenically stable and network compatible quantum-emitter module for memory use. This quantum-emitter module is a significant development towards advanced quantum networking applications such as distributed sensing and processing.
• Score: 0.2967921768537104
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Realizing a quantum network will require long-lived quantum memories with optical interfaces incorporated into a scalable architecture. Color centers quantum emitters in diamond have emerged as a promising memory modality due to their optical properties and compatibility with scalable integration. However, developing a scalable color center emitter module requires significant advances in the areas of heterogeneous integration and cryogenically compatible packaging. Here we report on a cryogenically stable and network compatible quantum-emitter module for memory use. This quantum-emitter module is a significant development towards advanced quantum networking applications such as distributed sensing and processing.

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