{"publisher":"Wiley","external_id":{"arxiv":["2208.10703"]},"date_created":"2023-11-05T23:00:54Z","month":"12","publication_status":"published","issue":"12","publication":"Laser and Photonics Reviews","doi":"10.1002/lpor.202200866","oa_version":"Preprint","department":[{"_id":"JoFi"}],"user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","type":"journal_article","date_updated":"2024-01-30T14:36:42Z","acknowledgement":"This work was supported by the National Key Research and Development Program of China (Grant no. 2022YFA1405200), the National Natural Science Foundation of China (Nos. 92265202), and the European Research Council (ERC CoG Q-ECHOS, 101001005).","_id":"14489","status":"public","article_type":"original","oa":1,"abstract":[{"text":"Microwave-optics entanglement is a vital component for building hybrid quantum networks. Here, a new mechanism for preparing stationary entanglement between microwave and optical cavity fields in a cavity optomagnomechanical system is proposed. It consists of a magnon mode in a ferrimagnetic crystal that couples directly to a microwave cavity mode via the magnetic dipole interaction and indirectly to an optical cavity through the deformation displacement of the crystal. The mechanical displacement is induced by the magnetostrictive force and coupled to the optical cavity via radiation pressure. Both the opto- and magnomechanical couplings are dispersive. Magnon–phonon entanglement is created via magnomechanical parametric down-conversion, which is further distributed to optical and microwave photons via simultaneous optomechanical beamsplitter interaction and electromagnonic state-swap interaction, yielding stationary microwave-optics entanglement. The microwave-optics entanglement is robust against thermal noise, which will find broad potential applications in quantum networks and quantum information processing with hybrid quantum systems.","lang":"eng"}],"year":"2023","main_file_link":[{"url":"https://doi.org/10.48550/arXiv.2208.10703","open_access":"1"}],"language":[{"iso":"eng"}],"day":"01","author":[{"full_name":"Fan, Zhi Yuan","first_name":"Zhi Yuan","last_name":"Fan"},{"last_name":"Qiu","orcid":"0000-0003-4345-4267","first_name":"Liu","id":"45e99c0d-1eb1-11eb-9b96-ed8ab2983cac","full_name":"Qiu, Liu"},{"last_name":"Gröblacher","first_name":"Simon","full_name":"Gröblacher, Simon"},{"full_name":"Li, Jie","first_name":"Jie","last_name":"Li"}],"article_number":"2200866","article_processing_charge":"No","citation":{"mla":"Fan, Zhi Yuan, et al. “Microwave-Optics Entanglement via Cavity Optomagnomechanics.” Laser and Photonics Reviews, vol. 17, no. 12, 2200866, Wiley, 2023, doi:10.1002/lpor.202200866.","ista":"Fan ZY, Qiu L, Gröblacher S, Li J. 2023. Microwave-optics entanglement via cavity optomagnomechanics. Laser and Photonics Reviews. 17(12), 2200866.","ieee":"Z. Y. Fan, L. Qiu, S. Gröblacher, and J. Li, “Microwave-optics entanglement via cavity optomagnomechanics,” Laser and Photonics Reviews, vol. 17, no. 12. Wiley, 2023.","ama":"Fan ZY, Qiu L, Gröblacher S, Li J. Microwave-optics entanglement via cavity optomagnomechanics. Laser and Photonics Reviews. 2023;17(12). doi:10.1002/lpor.202200866","apa":"Fan, Z. Y., Qiu, L., Gröblacher, S., & Li, J. (2023). Microwave-optics entanglement via cavity optomagnomechanics. Laser and Photonics Reviews. Wiley. https://doi.org/10.1002/lpor.202200866","chicago":"Fan, Zhi Yuan, Liu Qiu, Simon Gröblacher, and Jie Li. “Microwave-Optics Entanglement via Cavity Optomagnomechanics.” Laser and Photonics Reviews. Wiley, 2023. https://doi.org/10.1002/lpor.202200866.","short":"Z.Y. Fan, L. Qiu, S. Gröblacher, J. Li, Laser and Photonics Reviews 17 (2023)."},"intvolume":" 17","title":"Microwave-optics entanglement via cavity optomagnomechanics","publication_identifier":{"eissn":["1863-8899"],"issn":["1863-8880"]},"scopus_import":"1","quality_controlled":"1","date_published":"2023-12-01T00:00:00Z","volume":17}