[{"author":[{"full_name":"Zemlicka, Martin","last_name":"Zemlicka","first_name":"Martin","id":"2DCF8DE6-F248-11E8-B48F-1D18A9856A87"},{"full_name":"Redchenko, Elena","last_name":"Redchenko","first_name":"Elena","id":"2C21D6E8-F248-11E8-B48F-1D18A9856A87"},{"orcid":"0000-0002-3415-4628","full_name":"Peruzzo, Matilda","last_name":"Peruzzo","first_name":"Matilda","id":"3F920B30-F248-11E8-B48F-1D18A9856A87"},{"orcid":"0000-0001-6937-5773","full_name":"Hassani, Farid","last_name":"Hassani","first_name":"Farid","id":"2AED110C-F248-11E8-B48F-1D18A9856A87"},{"id":"42F71B44-F248-11E8-B48F-1D18A9856A87","first_name":"Andrea","last_name":"Trioni","full_name":"Trioni, Andrea"},{"last_name":"Barzanjeh","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir"},{"id":"4B591CBA-F248-11E8-B48F-1D18A9856A87","first_name":"Johannes M","full_name":"Fink, Johannes M","orcid":"0000-0001-8112-028X","last_name":"Fink"}],"external_id":{"arxiv":["2206.14104"]},"article_processing_charge":"No","title":"Compact vacuum-gap transmon qubits: Selective and sensitive probes for superconductor surface losses","citation":{"ieee":"M. Zemlicka et al., “Compact vacuum-gap transmon qubits: Selective and sensitive probes for superconductor surface losses,” Physical Review Applied, vol. 20, no. 4. American Physical Society, 2023.","short":"M. Zemlicka, E. Redchenko, M. Peruzzo, F. Hassani, A. Trioni, S. Barzanjeh, J.M. Fink, Physical Review Applied 20 (2023).","ama":"Zemlicka M, Redchenko E, Peruzzo M, et al. Compact vacuum-gap transmon qubits: Selective and sensitive probes for superconductor surface losses. Physical Review Applied. 2023;20(4). doi:10.1103/PhysRevApplied.20.044054","apa":"Zemlicka, M., Redchenko, E., Peruzzo, M., Hassani, F., Trioni, A., Barzanjeh, S., & Fink, J. M. (2023). Compact vacuum-gap transmon qubits: Selective and sensitive probes for superconductor surface losses. Physical Review Applied. American Physical Society. https://doi.org/10.1103/PhysRevApplied.20.044054","mla":"Zemlicka, Martin, et al. “Compact Vacuum-Gap Transmon Qubits: Selective and Sensitive Probes for Superconductor Surface Losses.” Physical Review Applied, vol. 20, no. 4, 044054, American Physical Society, 2023, doi:10.1103/PhysRevApplied.20.044054.","ista":"Zemlicka M, Redchenko E, Peruzzo M, Hassani F, Trioni A, Barzanjeh S, Fink JM. 2023. Compact vacuum-gap transmon qubits: Selective and sensitive probes for superconductor surface losses. Physical Review Applied. 20(4), 044054.","chicago":"Zemlicka, Martin, Elena Redchenko, Matilda Peruzzo, Farid Hassani, Andrea Trioni, Shabir Barzanjeh, and Johannes M Fink. “Compact Vacuum-Gap Transmon Qubits: Selective and Sensitive Probes for Superconductor Surface Losses.” Physical Review Applied. American Physical Society, 2023. https://doi.org/10.1103/PhysRevApplied.20.044054."},"user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","project":[{"call_identifier":"FWF","_id":"26927A52-B435-11E9-9278-68D0E5697425","grant_number":"F07105","name":"Integrating superconducting quantum circuits"},{"grant_number":"758053","name":"A Fiber Optic Transceiver for Superconducting Qubits","_id":"26336814-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"},{"name":"Protected states of quantum matter","_id":"eb9b30ac-77a9-11ec-83b8-871f581d53d2"},{"grant_number":"707438","name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics SUPEREOM","call_identifier":"H2020","_id":"258047B6-B435-11E9-9278-68D0E5697425"},{"name":"Open Superconducting Quantum Computers (OpenSuperQPlus)","grant_number":"101080139","_id":"bdb7cfc1-d553-11ed-ba76-d2eaab167738"}],"article_number":"044054","date_published":"2023-10-20T00:00:00Z","doi":"10.1103/PhysRevApplied.20.044054","date_created":"2023-11-12T23:00:55Z","year":"2023","day":"20","publication":"Physical Review Applied","quality_controlled":"1","publisher":"American Physical Society","oa":1,"acknowledgement":"This work was supported by the Austrian Science Fund (FWF) through BeyondC (F7105), the European Research Council under Grant Agreement No. 758053 (ERC StG QUNNECT) and a NOMIS foundation research grant. M.Z. was the recipient of a SAIA scholarship, E.R. of\r\na DOC fellowship of the Austrian Academy of Sciences, and M.P. of a Pöttinger scholarship at IST Austria. S.B. acknowledges support from Marie Skłodowska Curie Program No. 707438 (MSC-IF SUPEREOM). J.M.F. acknowledges support from the Horizon Europe Program HORIZON-CL4-2022-QUANTUM-01-SGA via Project No. 101113946 OpenSuperQPlus100 and the ISTA Nanofabrication Facility.","department":[{"_id":"JoFi"}],"date_updated":"2023-11-13T09:22:47Z","type":"journal_article","article_type":"original","status":"public","_id":"14517","issue":"4","volume":20,"related_material":{"record":[{"id":"14520","status":"public","relation":"research_data"}]},"ec_funded":1,"publication_identifier":{"eissn":["2331-7019"]},"publication_status":"published","language":[{"iso":"eng"}],"scopus_import":"1","main_file_link":[{"url":"https://arxiv.org/abs/2206.14104","open_access":"1"}],"month":"10","intvolume":" 20","abstract":[{"text":"State-of-the-art transmon qubits rely on large capacitors, which systematically improve their coherence due to reduced surface-loss participation. However, this approach increases both the footprint and the parasitic cross-coupling and is ultimately limited by radiation losses—a potential roadblock for scaling up quantum processors to millions of qubits. In this work we present transmon qubits with sizes as low as 36 × 39 µm2 with 100-nm-wide vacuum-gap capacitors that are micromachined from commercial silicon-on-insulator wafers and shadow evaporated with aluminum. We achieve a vacuum participation ratio up to 99.6% in an in-plane design that is compatible with standard coplanar circuits. Qubit relaxationtime measurements for small gaps with high zero-point electric field variance of up to 22 V/m reveal a double exponential decay indicating comparably strong qubit interaction with long-lived two-level systems. The exceptionally high selectivity of up to 20 dB to the superconductor-vacuum interface allows us to precisely back out the sub-single-photon dielectric loss tangent of aluminum oxide previously exposed to ambient conditions. In terms of future scaling potential, we achieve a ratio of qubit quality factor to a footprint area equal to 20 µm−2, which is comparable with the highest T1 devices relying on larger geometries, a value that could improve substantially for lower surface-loss superconductors. ","lang":"eng"}],"acknowledged_ssus":[{"_id":"NanoFab"}],"oa_version":"Preprint"},{"day":"28","year":"2022","has_accepted_license":"1","license":"https://creativecommons.org/publicdomain/zero/1.0/","date_created":"2023-11-13T08:09:10Z","doi":"10.5281/ZENODO.8408897","related_material":{"record":[{"relation":"used_in_publication","id":"14517","status":"public"}]},"date_published":"2022-06-28T00:00:00Z","oa_version":"Published Version","abstract":[{"lang":"eng","text":"This dataset comprises all data shown in the figures of the submitted article \"Compact vacuum gap transmon qubits: Selective and sensitive probes for superconductor surface losses\" at arxiv.org/abs/2206.14104. Additional raw data are available from the corresponding author on reasonable request."}],"month":"06","oa":1,"main_file_link":[{"url":"https://doi.org/10.5281/ZENODO.8408897","open_access":"1"}],"publisher":"Zenodo","ddc":["530"],"user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","citation":{"chicago":"Zemlicka, Martin, Elena Redchenko, Matilda Peruzzo, Farid Hassani, Andrea Trioni, Shabir Barzanjeh, and Johannes M Fink. “Compact Vacuum Gap Transmon Qubits: Selective and Sensitive Probes for Superconductor Surface Losses.” Zenodo, 2022. https://doi.org/10.5281/ZENODO.8408897.","ista":"Zemlicka M, Redchenko E, Peruzzo M, Hassani F, Trioni A, Barzanjeh S, Fink JM. 2022. Compact vacuum gap transmon qubits: Selective and sensitive probes for superconductor surface losses, Zenodo, 10.5281/ZENODO.8408897.","mla":"Zemlicka, Martin, et al. Compact Vacuum Gap Transmon Qubits: Selective and Sensitive Probes for Superconductor Surface Losses. Zenodo, 2022, doi:10.5281/ZENODO.8408897.","short":"M. Zemlicka, E. Redchenko, M. Peruzzo, F. Hassani, A. Trioni, S. Barzanjeh, J.M. Fink, (2022).","ieee":"M. Zemlicka et al., “Compact vacuum gap transmon qubits: Selective and sensitive probes for superconductor surface losses.” Zenodo, 2022.","apa":"Zemlicka, M., Redchenko, E., Peruzzo, M., Hassani, F., Trioni, A., Barzanjeh, S., & Fink, J. M. (2022). Compact vacuum gap transmon qubits: Selective and sensitive probes for superconductor surface losses. Zenodo. https://doi.org/10.5281/ZENODO.8408897","ama":"Zemlicka M, Redchenko E, Peruzzo M, et al. Compact vacuum gap transmon qubits: Selective and sensitive probes for superconductor surface losses. 2022. doi:10.5281/ZENODO.8408897"},"date_updated":"2023-11-13T09:22:48Z","title":"Compact vacuum gap transmon qubits: Selective and sensitive probes for superconductor surface losses","department":[{"_id":"JoFi"}],"article_processing_charge":"No","author":[{"id":"2DCF8DE6-F248-11E8-B48F-1D18A9856A87","first_name":"Martin","last_name":"Zemlicka","full_name":"Zemlicka, Martin"},{"full_name":"Redchenko, Elena","last_name":"Redchenko","first_name":"Elena","id":"2C21D6E8-F248-11E8-B48F-1D18A9856A87"},{"last_name":"Peruzzo","orcid":"0000-0002-3415-4628","full_name":"Peruzzo, Matilda","id":"3F920B30-F248-11E8-B48F-1D18A9856A87","first_name":"Matilda"},{"full_name":"Hassani, Farid","orcid":"0000-0001-6937-5773","last_name":"Hassani","first_name":"Farid","id":"2AED110C-F248-11E8-B48F-1D18A9856A87"},{"id":"42F71B44-F248-11E8-B48F-1D18A9856A87","first_name":"Andrea","last_name":"Trioni","full_name":"Trioni, Andrea"},{"first_name":"Shabir","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","last_name":"Barzanjeh","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir"},{"first_name":"Johannes M","id":"4B591CBA-F248-11E8-B48F-1D18A9856A87","last_name":"Fink","full_name":"Fink, Johannes M","orcid":"0000-0001-8112-028X"}],"_id":"14520","status":"public","tmp":{"image":"/images/cc_0.png","legal_code_url":"https://creativecommons.org/publicdomain/zero/1.0/legalcode","name":"Creative Commons Public Domain Dedication (CC0 1.0)","short":"CC0 (1.0)"},"type":"research_data_reference"},{"related_material":{"record":[{"relation":"research_data","id":"13056","status":"public"}],"link":[{"url":"https://doi.org/10.1038/s41467-020-18912-9","relation":"erratum"},{"relation":"press_release","url":"https://ist.ac.at/en/news/how-to-transport-microwave-quantum-information-via-optical-fiber/","description":"News on IST Homepage"}]},"volume":11,"ec_funded":1,"file":[{"file_id":"8530","checksum":"88f92544889eb18bb38e25629a422a86","success":1,"access_level":"open_access","relation":"main_file","content_type":"application/pdf","date_created":"2020-09-18T13:02:37Z","file_name":"2020_NatureComm_Arnold.pdf","creator":"dernst","date_updated":"2020-09-18T13:02:37Z","file_size":1002818}],"language":[{"iso":"eng"}],"publication_identifier":{"issn":["2041-1723"]},"publication_status":"published","month":"09","intvolume":" 11","oa_version":"Published Version","acknowledged_ssus":[{"_id":"NanoFab"}],"abstract":[{"lang":"eng","text":"Practical quantum networks require low-loss and noise-resilient optical interconnects as well as non-Gaussian resources for entanglement distillation and distributed quantum computation. The latter could be provided by superconducting circuits but existing solutions to interface the microwave and optical domains lack either scalability or efficiency, and in most cases the conversion noise is not known. In this work we utilize the unique opportunities of silicon photonics, cavity optomechanics and superconducting circuits to demonstrate a fully integrated, coherent transducer interfacing the microwave X and the telecom S bands with a total (internal) bidirectional transduction efficiency of 1.2% (135%) at millikelvin temperatures. The coupling relies solely on the radiation pressure interaction mediated by the femtometer-scale motion of two silicon nanobeams reaching a Vπ as low as 16 μV for sub-nanowatt pump powers. Without the associated optomechanical gain, we achieve a total (internal) pure conversion efficiency of up to 0.019% (1.6%), relevant for future noise-free operation on this qubit-compatible platform."}],"department":[{"_id":"JoFi"}],"file_date_updated":"2020-09-18T13:02:37Z","ddc":["530"],"date_updated":"2023-08-22T09:27:12Z","status":"public","keyword":["General Biochemistry","Genetics and Molecular Biology","General Physics and Astronomy","General Chemistry"],"article_type":"original","type":"journal_article","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","image":"/images/cc_by.png","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","short":"CC BY (4.0)"},"_id":"8529","doi":"10.1038/s41467-020-18269-z","date_published":"2020-09-08T00:00:00Z","date_created":"2020-09-18T10:56:20Z","day":"08","publication":"Nature Communications","isi":1,"has_accepted_license":"1","year":"2020","publisher":"Springer Nature","quality_controlled":"1","oa":1,"acknowledgement":"We thank Yuan Chen for performing supplementary FEM simulations and Andrew Higginbotham, Ralf Riedinger, Sungkun Hong, and Lorenzo Magrini for valuable discussions. This work was supported by IST Austria, the IST nanofabrication facility (NFF), the European Union’s Horizon 2020 research and innovation program under grant agreement no. 732894 (FET Proactive HOT) and the European Research Council under grant agreement no. 758053 (ERC StG QUNNECT). G.A. is the recipient of a DOC fellowship of the Austrian Academy of Sciences at IST Austria. W.H. is the recipient of an ISTplus postdoctoral fellowship with funding from the European Union’s Horizon 2020 research and innovation program under the Marie Sklodowska-Curie grant agreement no. 754411. J.M.F. acknowledges support from the Austrian Science Fund (FWF) through BeyondC (F71), a NOMIS foundation research grant, and the EU’s Horizon 2020 research and innovation program under grant agreement no. 862644 (FET Open QUARTET).","title":"Converting microwave and telecom photons with a silicon photonic nanomechanical interface","author":[{"orcid":"0000-0003-1397-7876","full_name":"Arnold, Georg M","last_name":"Arnold","first_name":"Georg M","id":"3770C838-F248-11E8-B48F-1D18A9856A87"},{"full_name":"Wulf, Matthias","orcid":"0000-0001-6613-1378","last_name":"Wulf","id":"45598606-F248-11E8-B48F-1D18A9856A87","first_name":"Matthias"},{"last_name":"Barzanjeh","full_name":"Barzanjeh, Shabir","orcid":"0000-0003-0415-1423","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir"},{"id":"2C21D6E8-F248-11E8-B48F-1D18A9856A87","first_name":"Elena","last_name":"Redchenko","full_name":"Redchenko, Elena"},{"id":"3B82B0F8-F248-11E8-B48F-1D18A9856A87","first_name":"Alfredo R","full_name":"Rueda Sanchez, Alfredo R","orcid":"0000-0001-6249-5860","last_name":"Rueda Sanchez"},{"full_name":"Hease, William J","orcid":"0000-0001-9868-2166","last_name":"Hease","id":"29705398-F248-11E8-B48F-1D18A9856A87","first_name":"William J"},{"id":"2AED110C-F248-11E8-B48F-1D18A9856A87","first_name":"Farid","full_name":"Hassani, Farid","orcid":"0000-0001-6937-5773","last_name":"Hassani"},{"orcid":"0000-0001-8112-028X","full_name":"Fink, Johannes M","last_name":"Fink","id":"4B591CBA-F248-11E8-B48F-1D18A9856A87","first_name":"Johannes M"}],"external_id":{"isi":["000577280200001"]},"article_processing_charge":"No","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","citation":{"ista":"Arnold GM, Wulf M, Barzanjeh S, Redchenko E, Rueda Sanchez AR, Hease WJ, Hassani F, Fink JM. 2020. Converting microwave and telecom photons with a silicon photonic nanomechanical interface. Nature Communications. 11, 4460.","chicago":"Arnold, Georg M, Matthias Wulf, Shabir Barzanjeh, Elena Redchenko, Alfredo R Rueda Sanchez, William J Hease, Farid Hassani, and Johannes M Fink. “Converting Microwave and Telecom Photons with a Silicon Photonic Nanomechanical Interface.” Nature Communications. Springer Nature, 2020. https://doi.org/10.1038/s41467-020-18269-z.","short":"G.M. Arnold, M. Wulf, S. Barzanjeh, E. Redchenko, A.R. Rueda Sanchez, W.J. Hease, F. Hassani, J.M. Fink, Nature Communications 11 (2020).","ieee":"G. M. Arnold et al., “Converting microwave and telecom photons with a silicon photonic nanomechanical interface,” Nature Communications, vol. 11. Springer Nature, 2020.","ama":"Arnold GM, Wulf M, Barzanjeh S, et al. Converting microwave and telecom photons with a silicon photonic nanomechanical interface. Nature Communications. 2020;11. doi:10.1038/s41467-020-18269-z","apa":"Arnold, G. M., Wulf, M., Barzanjeh, S., Redchenko, E., Rueda Sanchez, A. R., Hease, W. J., … Fink, J. M. (2020). Converting microwave and telecom photons with a silicon photonic nanomechanical interface. Nature Communications. Springer Nature. https://doi.org/10.1038/s41467-020-18269-z","mla":"Arnold, Georg M., et al. “Converting Microwave and Telecom Photons with a Silicon Photonic Nanomechanical Interface.” Nature Communications, vol. 11, 4460, Springer Nature, 2020, doi:10.1038/s41467-020-18269-z."},"project":[{"grant_number":"732894","name":"Hybrid Optomechanical Technologies","call_identifier":"H2020","_id":"257EB838-B435-11E9-9278-68D0E5697425"},{"call_identifier":"H2020","_id":"26336814-B435-11E9-9278-68D0E5697425","grant_number":"758053","name":"A Fiber Optic Transceiver for Superconducting Qubits"},{"grant_number":"754411","name":"ISTplus - Postdoctoral Fellowships","call_identifier":"H2020","_id":"260C2330-B435-11E9-9278-68D0E5697425"},{"call_identifier":"H2020","_id":"237CBA6C-32DE-11EA-91FC-C7463DDC885E","name":"Quantum readout techniques and technologies","grant_number":"862644"},{"_id":"2671EB66-B435-11E9-9278-68D0E5697425","name":"Coherent on-chip conversion of superconducting qubit signals from microwaves to optical frequencies"}],"article_number":"4460"},{"ddc":["530"],"user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","citation":{"mla":"Arnold, Georg M., et al. Converting Microwave and Telecom Photons with a Silicon Photonic Nanomechanical Interface. Zenodo, 2020, doi:10.5281/ZENODO.3961561.","ieee":"G. M. Arnold et al., “Converting microwave and telecom photons with a silicon photonic nanomechanical interface.” Zenodo, 2020.","short":"G.M. Arnold, M. Wulf, S. Barzanjeh, E. Redchenko, A.R. Rueda Sanchez, W.J. Hease, F. Hassani, J.M. Fink, (2020).","ama":"Arnold GM, Wulf M, Barzanjeh S, et al. Converting microwave and telecom photons with a silicon photonic nanomechanical interface. 2020. doi:10.5281/ZENODO.3961561","apa":"Arnold, G. M., Wulf, M., Barzanjeh, S., Redchenko, E., Rueda Sanchez, A. R., Hease, W. J., … Fink, J. M. (2020). Converting microwave and telecom photons with a silicon photonic nanomechanical interface. Zenodo. https://doi.org/10.5281/ZENODO.3961561","chicago":"Arnold, Georg M, Matthias Wulf, Shabir Barzanjeh, Elena Redchenko, Alfredo R Rueda Sanchez, William J Hease, Farid Hassani, and Johannes M Fink. “Converting Microwave and Telecom Photons with a Silicon Photonic Nanomechanical Interface.” Zenodo, 2020. https://doi.org/10.5281/ZENODO.3961561.","ista":"Arnold GM, Wulf M, Barzanjeh S, Redchenko E, Rueda Sanchez AR, Hease WJ, Hassani F, Fink JM. 2020. Converting microwave and telecom photons with a silicon photonic nanomechanical interface, Zenodo, 10.5281/ZENODO.3961561."},"date_updated":"2023-08-22T09:27:11Z","department":[{"_id":"JoFi"}],"title":"Converting microwave and telecom photons with a silicon photonic nanomechanical interface","author":[{"last_name":"Arnold","orcid":"0000-0003-1397-7876","full_name":"Arnold, Georg M","first_name":"Georg M","id":"3770C838-F248-11E8-B48F-1D18A9856A87"},{"last_name":"Wulf","orcid":"0000-0001-6613-1378","full_name":"Wulf, Matthias","first_name":"Matthias","id":"45598606-F248-11E8-B48F-1D18A9856A87"},{"first_name":"Shabir","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","last_name":"Barzanjeh","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir"},{"last_name":"Redchenko","full_name":"Redchenko, Elena","id":"2C21D6E8-F248-11E8-B48F-1D18A9856A87","first_name":"Elena"},{"last_name":"Rueda Sanchez","full_name":"Rueda Sanchez, Alfredo R","orcid":"0000-0001-6249-5860","id":"3B82B0F8-F248-11E8-B48F-1D18A9856A87","first_name":"Alfredo R"},{"full_name":"Hease, William J","orcid":"0000-0001-9868-2166","last_name":"Hease","first_name":"William J","id":"29705398-F248-11E8-B48F-1D18A9856A87"},{"full_name":"Hassani, Farid","orcid":"0000-0001-6937-5773","last_name":"Hassani","id":"2AED110C-F248-11E8-B48F-1D18A9856A87","first_name":"Farid"},{"first_name":"Johannes M","id":"4B591CBA-F248-11E8-B48F-1D18A9856A87","last_name":"Fink","full_name":"Fink, Johannes M","orcid":"0000-0001-8112-028X"}],"article_processing_charge":"No","_id":"13056","status":"public","type":"research_data_reference","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","image":"/images/cc_by.png","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","short":"CC BY (4.0)"},"day":"27","year":"2020","date_published":"2020-07-27T00:00:00Z","doi":"10.5281/ZENODO.3961561","related_material":{"record":[{"id":"8529","status":"public","relation":"used_in_publication"}]},"date_created":"2023-05-23T13:37:41Z","oa_version":"Published Version","abstract":[{"text":"This datasets comprises all data shown in plots of the submitted article \"Converting microwave and telecom photons with a silicon photonic nanomechanical interface\". Additional raw data are available from the corresponding author on reasonable request.","lang":"eng"}],"month":"07","publisher":"Zenodo","main_file_link":[{"url":"https://doi.org/10.5281/zenodo.3961562","open_access":"1"}],"oa":1},{"date_updated":"2023-08-24T11:10:49Z","ddc":["530"],"department":[{"_id":"JoFi"}],"file_date_updated":"2020-07-14T12:48:05Z","_id":"7910","article_type":"original","type":"journal_article","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","image":"/images/cc_by.png","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","short":"CC BY (4.0)"},"status":"public","publication_identifier":{"eissn":["23752548"]},"publication_status":"published","file":[{"creator":"dernst","file_size":795822,"date_updated":"2020-07-14T12:48:05Z","file_name":"2020_ScienceAdvances_Barzanjeh.pdf","date_created":"2020-06-02T09:18:36Z","relation":"main_file","access_level":"open_access","content_type":"application/pdf","checksum":"16fa61cc1951b444ee74c07188cda9da","file_id":"7913"}],"language":[{"iso":"eng"}],"volume":6,"related_material":{"link":[{"description":"News on IST Homepage","relation":"press_release","url":"https://ist.ac.at/en/news/scientists-demonstrate-quantum-radar-prototype/"}],"record":[{"relation":"later_version","id":"9001","status":"public"}]},"issue":"19","ec_funded":1,"abstract":[{"text":"Quantum illumination uses entangled signal-idler photon pairs to boost the detection efficiency of low-reflectivity objects in environments with bright thermal noise. Its advantage is particularly evident at low signal powers, a promising feature for applications such as noninvasive biomedical scanning or low-power short-range radar. Here, we experimentally investigate the concept of quantum illumination at microwave frequencies. We generate entangled fields to illuminate a room-temperature object at a distance of 1 m in a free-space detection setup. We implement a digital phase-conjugate receiver based on linear quadrature measurements that outperforms a symmetric classical noise radar in the same conditions, despite the entanglement-breaking signal path. Starting from experimental data, we also simulate the case of perfect idler photon number detection, which results in a quantum advantage compared with the relative classical benchmark. Our results highlight the opportunities and challenges in the way toward a first room-temperature application of microwave quantum circuits.","lang":"eng"}],"oa_version":"Published Version","scopus_import":"1","month":"05","intvolume":" 6","citation":{"ista":"Barzanjeh S, Pirandola S, Vitali D, Fink JM. 2020. Microwave quantum illumination using a digital receiver. Science Advances. 6(19), eabb0451.","chicago":"Barzanjeh, Shabir, S. Pirandola, D Vitali, and Johannes M Fink. “Microwave Quantum Illumination Using a Digital Receiver.” Science Advances. AAAS, 2020. https://doi.org/10.1126/sciadv.abb0451.","short":"S. Barzanjeh, S. Pirandola, D. Vitali, J.M. Fink, Science Advances 6 (2020).","ieee":"S. Barzanjeh, S. Pirandola, D. Vitali, and J. M. Fink, “Microwave quantum illumination using a digital receiver,” Science Advances, vol. 6, no. 19. AAAS, 2020.","apa":"Barzanjeh, S., Pirandola, S., Vitali, D., & Fink, J. M. (2020). Microwave quantum illumination using a digital receiver. Science Advances. AAAS. https://doi.org/10.1126/sciadv.abb0451","ama":"Barzanjeh S, Pirandola S, Vitali D, Fink JM. Microwave quantum illumination using a digital receiver. Science Advances. 2020;6(19). doi:10.1126/sciadv.abb0451","mla":"Barzanjeh, Shabir, et al. “Microwave Quantum Illumination Using a Digital Receiver.” Science Advances, vol. 6, no. 19, eabb0451, AAAS, 2020, doi:10.1126/sciadv.abb0451."},"user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","author":[{"id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir","last_name":"Barzanjeh"},{"full_name":"Pirandola, S.","last_name":"Pirandola","first_name":"S."},{"last_name":"Vitali","full_name":"Vitali, D","first_name":"D"},{"first_name":"Johannes M","id":"4B591CBA-F248-11E8-B48F-1D18A9856A87","last_name":"Fink","orcid":"0000-0001-8112-028X","full_name":"Fink, Johannes M"}],"external_id":{"arxiv":["1908.03058"],"isi":["000531171100045"]},"article_processing_charge":"No","title":"Microwave quantum illumination using a digital receiver","article_number":"eabb0451","project":[{"call_identifier":"H2020","_id":"26336814-B435-11E9-9278-68D0E5697425","name":"A Fiber Optic Transceiver for Superconducting Qubits","grant_number":"758053"},{"_id":"237CBA6C-32DE-11EA-91FC-C7463DDC885E","call_identifier":"H2020","grant_number":"862644","name":"Quantum readout techniques and technologies"},{"name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics SUPEREOM","grant_number":"707438","_id":"258047B6-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"},{"_id":"257EB838-B435-11E9-9278-68D0E5697425","call_identifier":"H2020","name":"Hybrid Optomechanical Technologies","grant_number":"732894"},{"name":"Integrating superconducting quantum circuits","grant_number":"F07105","_id":"26927A52-B435-11E9-9278-68D0E5697425","call_identifier":"FWF"}],"isi":1,"has_accepted_license":"1","year":"2020","day":"06","publication":"Science Advances","doi":"10.1126/sciadv.abb0451","date_published":"2020-05-06T00:00:00Z","date_created":"2020-05-31T22:00:49Z","publisher":"AAAS","quality_controlled":"1","oa":1},{"main_file_link":[{"open_access":"1","url":"https://arxiv.org/abs/1908.03058"}],"scopus_import":"1","intvolume":" 2020","month":"09","abstract":[{"lang":"eng","text":"Quantum illumination is a sensing technique that employs entangled signal-idler beams to improve the detection efficiency of low-reflectivity objects in environments with large thermal noise. The advantage over classical strategies is evident at low signal brightness, a feature which could make the protocol an ideal prototype for non-invasive scanning or low-power short-range radar. Here we experimentally investigate the concept of quantum illumination at microwave frequencies, by generating entangled fields using a Josephson parametric converter which are then amplified to illuminate a room-temperature object at a distance of 1 meter. Starting from experimental data, we simulate the case of perfect idler photon number detection, which results in a quantum advantage compared to the relative classical benchmark. Our results highlight the opportunities and challenges on the way towards a first room-temperature application of microwave quantum circuits."}],"oa_version":"Preprint","ec_funded":1,"volume":2020,"issue":"9","related_material":{"record":[{"id":"7910","status":"public","relation":"earlier_version"}]},"publication_status":"published","publication_identifier":{"issn":["1097-5659"],"isbn":["9781728189420"]},"language":[{"iso":"eng"}],"conference":{"name":"RadarConf: National Conference on Radar","end_date":"2020-09-25","location":"Florence, Italy","start_date":"2020-09-21"},"type":"conference","status":"public","_id":"9001","department":[{"_id":"JoFi"}],"date_updated":"2023-08-24T11:10:49Z","oa":1,"publisher":"IEEE","quality_controlled":"1","acknowledgement":"This work was supported by the Institute of Science and Technology Austria (IST Austria), the European Research Council under grant agreement number 758053 (ERC StG QUNNECT) and the EU’s Horizon 2020 research and innovation programme under grant agreement number 862644 (FET Open QUARTET). S.B. acknowledges support from the Marie Skłodowska Curie\r\nfellowship number 707438 (MSC-IF SUPEREOM), DV acknowledge support from EU’s Horizon 2020 research and innovation programme under grant agreement number 732894 (FET Proactive HOT) and the Project QuaSeRT funded by the QuantERA ERANET Cofund in Quantum Technologies, and J.M.F from the Austrian Science Fund (FWF) through BeyondC (F71), a NOMIS foundation research grant, and the EU’s Horizon 2020 research and\r\ninnovation programme under grant agreement number 732894 (FET Proactive\r\nHOT).","date_created":"2021-01-10T23:01:17Z","doi":"10.1109/RadarConf2043947.2020.9266397","date_published":"2020-09-21T00:00:00Z","year":"2020","isi":1,"publication":"IEEE National Radar Conference - Proceedings","day":"21","project":[{"name":"A Fiber Optic Transceiver for Superconducting Qubits","grant_number":"758053","call_identifier":"H2020","_id":"26336814-B435-11E9-9278-68D0E5697425"},{"call_identifier":"H2020","_id":"237CBA6C-32DE-11EA-91FC-C7463DDC885E","grant_number":"862644","name":"Quantum readout techniques and technologies"},{"_id":"258047B6-B435-11E9-9278-68D0E5697425","call_identifier":"H2020","grant_number":"707438","name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics SUPEREOM"},{"grant_number":"732894","name":"Hybrid Optomechanical Technologies","_id":"257EB838-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"}],"article_number":"9266397","external_id":{"arxiv":["1908.03058"],"isi":["000612224900089"]},"article_processing_charge":"No","author":[{"last_name":"Barzanjeh","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir"},{"first_name":"Stefano","full_name":"Pirandola, Stefano","last_name":"Pirandola"},{"last_name":"Vitali","full_name":"Vitali, David","first_name":"David"},{"last_name":"Fink","full_name":"Fink, Johannes M","orcid":"0000-0001-8112-028X","id":"4B591CBA-F248-11E8-B48F-1D18A9856A87","first_name":"Johannes M"}],"title":"Microwave quantum illumination with a digital phase-conjugated receiver","citation":{"ista":"Barzanjeh S, Pirandola S, Vitali D, Fink JM. 2020. Microwave quantum illumination with a digital phase-conjugated receiver. IEEE National Radar Conference - Proceedings. RadarConf: National Conference on Radar vol. 2020, 9266397.","chicago":"Barzanjeh, Shabir, Stefano Pirandola, David Vitali, and Johannes M Fink. “Microwave Quantum Illumination with a Digital Phase-Conjugated Receiver.” In IEEE National Radar Conference - Proceedings, Vol. 2020. IEEE, 2020. https://doi.org/10.1109/RadarConf2043947.2020.9266397.","ama":"Barzanjeh S, Pirandola S, Vitali D, Fink JM. Microwave quantum illumination with a digital phase-conjugated receiver. In: IEEE National Radar Conference - Proceedings. Vol 2020. IEEE; 2020. doi:10.1109/RadarConf2043947.2020.9266397","apa":"Barzanjeh, S., Pirandola, S., Vitali, D., & Fink, J. M. (2020). Microwave quantum illumination with a digital phase-conjugated receiver. In IEEE National Radar Conference - Proceedings (Vol. 2020). Florence, Italy: IEEE. https://doi.org/10.1109/RadarConf2043947.2020.9266397","short":"S. Barzanjeh, S. Pirandola, D. Vitali, J.M. Fink, in:, IEEE National Radar Conference - Proceedings, IEEE, 2020.","ieee":"S. Barzanjeh, S. Pirandola, D. Vitali, and J. M. Fink, “Microwave quantum illumination with a digital phase-conjugated receiver,” in IEEE National Radar Conference - Proceedings, Florence, Italy, 2020, vol. 2020, no. 9.","mla":"Barzanjeh, Shabir, et al. “Microwave Quantum Illumination with a Digital Phase-Conjugated Receiver.” IEEE National Radar Conference - Proceedings, vol. 2020, no. 9, 9266397, IEEE, 2020, doi:10.1109/RadarConf2043947.2020.9266397."},"user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8"},{"year":"2020","has_accepted_license":"1","isi":1,"publication":"Quantum Science and Technology","day":"01","date_created":"2021-02-25T08:32:29Z","doi":"10.1088/2058-9565/ab788a","date_published":"2020-03-01T00:00:00Z","acknowledgement":"During the writing of this article we became aware of another review of quantum transduction with somewhat different emphasis [99].\r\nWe would like to thank the participants of the transduction workshop at Caltech in September 2018 for helpful and stimulating discussions. We particularly thank John Bartholomew, Andrei Faraon, Johannes Fink, Jeff Holzgrafe, Linbo Shao, Marko Lončar, Daniel Oblak, and Oskar Painter.\r\nN L and N S acknowledge support from the Alliance for Quantum Technologies' (AQT) Intelligent Quantum Networks and Technologies (INQNET) research program and by DOE/HEP QuantISED program grant, QCCFP (Quantum Communication Channels for Fundamental Physics), award number DE-SC0019219. NS further acknowledges support by the Natural Sciences and Engineering Research Council of Canada (NSERC). SB acknowledges support from the Marie Skłodowska Curie fellowship number 707 438 (MSC-IF SUPEREOM). JPC acknowledges support from the Caltech PMA prize postdoctoral fellowship. MS acknowledges support from the ARL-CDQI and the National Science Foundation. CS acknowledges NSERC, Quantum Alberta, and the Alberta Major Innovation Fund.","oa":1,"publisher":"IOP Publishing","quality_controlled":"1","citation":{"ista":"Lauk N, Sinclair N, Barzanjeh S, Covey JP, Saffman M, Spiropulu M, Simon C. 2020. Perspectives on quantum transduction. Quantum Science and Technology. 5(2), 020501.","chicago":"Lauk, Nikolai, Neil Sinclair, Shabir Barzanjeh, Jacob P Covey, Mark Saffman, Maria Spiropulu, and Christoph Simon. “Perspectives on Quantum Transduction.” Quantum Science and Technology. IOP Publishing, 2020. https://doi.org/10.1088/2058-9565/ab788a.","ieee":"N. Lauk et al., “Perspectives on quantum transduction,” Quantum Science and Technology, vol. 5, no. 2. IOP Publishing, 2020.","short":"N. Lauk, N. Sinclair, S. Barzanjeh, J.P. Covey, M. Saffman, M. Spiropulu, C. Simon, Quantum Science and Technology 5 (2020).","ama":"Lauk N, Sinclair N, Barzanjeh S, et al. Perspectives on quantum transduction. Quantum Science and Technology. 2020;5(2). doi:10.1088/2058-9565/ab788a","apa":"Lauk, N., Sinclair, N., Barzanjeh, S., Covey, J. P., Saffman, M., Spiropulu, M., & Simon, C. (2020). Perspectives on quantum transduction. Quantum Science and Technology. IOP Publishing. https://doi.org/10.1088/2058-9565/ab788a","mla":"Lauk, Nikolai, et al. “Perspectives on Quantum Transduction.” Quantum Science and Technology, vol. 5, no. 2, 020501, IOP Publishing, 2020, doi:10.1088/2058-9565/ab788a."},"user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","external_id":{"isi":["000521449500001"]},"article_processing_charge":"No","author":[{"first_name":"Nikolai","full_name":"Lauk, Nikolai","last_name":"Lauk"},{"last_name":"Sinclair","full_name":"Sinclair, Neil","first_name":"Neil"},{"id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir","last_name":"Barzanjeh","full_name":"Barzanjeh, Shabir","orcid":"0000-0003-0415-1423"},{"last_name":"Covey","full_name":"Covey, Jacob P","first_name":"Jacob P"},{"last_name":"Saffman","full_name":"Saffman, Mark","first_name":"Mark"},{"last_name":"Spiropulu","full_name":"Spiropulu, Maria","first_name":"Maria"},{"first_name":"Christoph","last_name":"Simon","full_name":"Simon, Christoph"}],"title":"Perspectives on quantum transduction","article_number":"020501","project":[{"name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics SUPEREOM","grant_number":"707438","_id":"258047B6-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"}],"publication_status":"published","publication_identifier":{"issn":["2058-9565"]},"language":[{"iso":"eng"}],"file":[{"content_type":"application/pdf","relation":"main_file","access_level":"open_access","success":1,"file_id":"9215","checksum":"a8562c42124a66b86836fe2489eb5f4f","file_size":974399,"date_updated":"2021-03-02T09:47:13Z","creator":"dernst","file_name":"2020_QuantumScience_Lauk.pdf","date_created":"2021-03-02T09:47:13Z"}],"ec_funded":1,"volume":5,"issue":"2","abstract":[{"lang":"eng","text":"Quantum transduction, the process of converting quantum signals from one form of energy to another, is an important area of quantum science and technology. The present perspective article reviews quantum transduction between microwave and optical photons, an area that has recently seen a lot of activity and progress because of its relevance for connecting superconducting quantum processors over long distances, among other applications. Our review covers the leading approaches to achieving such transduction, with an emphasis on those based on atomic ensembles, opto-electro-mechanics, and electro-optics. We briefly discuss relevant metrics from the point of view of different applications, as well as challenges for the future."}],"oa_version":"Published Version","scopus_import":"1","intvolume":" 5","month":"03","date_updated":"2023-08-24T11:17:48Z","ddc":["530"],"file_date_updated":"2021-03-02T09:47:13Z","department":[{"_id":"JoFi"}],"_id":"9194","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","image":"/images/cc_by.png","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","short":"CC BY (4.0)"},"type":"journal_article","article_type":"review","status":"public"},{"oa_version":"Preprint","abstract":[{"text":"Mechanical systems facilitate the development of a hybrid quantum technology comprising electrical, optical, atomic and acoustic degrees of freedom1, and entanglement is essential to realize quantum-enabled devices. Continuous-variable entangled fields—known as Einstein–Podolsky–Rosen (EPR) states—are spatially separated two-mode squeezed states that can be used for quantum teleportation and quantum communication2. In the optical domain, EPR states are typically generated using nondegenerate optical amplifiers3, and at microwave frequencies Josephson circuits can serve as a nonlinear medium4,5,6. An outstanding goal is to deterministically generate and distribute entangled states with a mechanical oscillator, which requires a carefully arranged balance between excitation, cooling and dissipation in an ultralow noise environment. Here we observe stationary emission of path-entangled microwave radiation from a parametrically driven 30-micrometre-long silicon nanostring oscillator, squeezing the joint field operators of two thermal modes by 3.40 decibels below the vacuum level. The motion of this micromechanical system correlates up to 50 photons per second per hertz, giving rise to a quantum discord that is robust with respect to microwave noise7. Such generalized quantum correlations of separable states are important for quantum-enhanced detection8 and provide direct evidence of the non-classical nature of the mechanical oscillator without directly measuring its state9. This noninvasive measurement scheme allows to infer information about otherwise inaccessible objects, with potential implications for sensing, open-system dynamics and fundamental tests of quantum gravity. In the future, similar on-chip devices could be used to entangle subsystems on very different energy scales, such as microwave and optical photons.","lang":"eng"}],"acknowledged_ssus":[{"_id":"NanoFab"}],"month":"06","intvolume":" 570","scopus_import":"1","main_file_link":[{"open_access":"1","url":"https://arxiv.org/abs/1809.05865"}],"language":[{"iso":"eng"}],"publication_status":"published","volume":570,"ec_funded":1,"_id":"6609","status":"public","type":"journal_article","date_updated":"2023-08-28T12:29:56Z","department":[{"_id":"JoFi"}],"quality_controlled":"1","publisher":"Nature Publishing Group","oa":1,"day":"27","publication":"Nature","isi":1,"year":"2019","doi":"10.1038/s41586-019-1320-2","date_published":"2019-06-27T00:00:00Z","date_created":"2019-07-07T21:59:20Z","page":"480-483","project":[{"grant_number":"732894","name":"Hybrid Optomechanical Technologies","call_identifier":"H2020","_id":"257EB838-B435-11E9-9278-68D0E5697425"},{"grant_number":"758053","name":"A Fiber Optic Transceiver for Superconducting Qubits","_id":"26336814-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"},{"name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics","grant_number":"707438","_id":"258047B6-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"},{"name":"Coherent on-chip conversion of superconducting qubit signals from microwaves to optical frequencies","_id":"2671EB66-B435-11E9-9278-68D0E5697425"}],"user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","citation":{"chicago":"Barzanjeh, Shabir, Elena Redchenko, Matilda Peruzzo, Matthias Wulf, Dylan Lewis, Georg M Arnold, and Johannes M Fink. “Stationary Entangled Radiation from Micromechanical Motion.” Nature. Nature Publishing Group, 2019. https://doi.org/10.1038/s41586-019-1320-2.","ista":"Barzanjeh S, Redchenko E, Peruzzo M, Wulf M, Lewis D, Arnold GM, Fink JM. 2019. Stationary entangled radiation from micromechanical motion. Nature. 570, 480–483.","mla":"Barzanjeh, Shabir, et al. “Stationary Entangled Radiation from Micromechanical Motion.” Nature, vol. 570, Nature Publishing Group, 2019, pp. 480–83, doi:10.1038/s41586-019-1320-2.","ieee":"S. Barzanjeh et al., “Stationary entangled radiation from micromechanical motion,” Nature, vol. 570. Nature Publishing Group, pp. 480–483, 2019.","short":"S. Barzanjeh, E. Redchenko, M. Peruzzo, M. Wulf, D. Lewis, G.M. Arnold, J.M. Fink, Nature 570 (2019) 480–483.","apa":"Barzanjeh, S., Redchenko, E., Peruzzo, M., Wulf, M., Lewis, D., Arnold, G. M., & Fink, J. M. (2019). Stationary entangled radiation from micromechanical motion. Nature. Nature Publishing Group. https://doi.org/10.1038/s41586-019-1320-2","ama":"Barzanjeh S, Redchenko E, Peruzzo M, et al. Stationary entangled radiation from micromechanical motion. Nature. 2019;570:480-483. doi:10.1038/s41586-019-1320-2"},"title":"Stationary entangled radiation from micromechanical motion","author":[{"orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir","last_name":"Barzanjeh","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir"},{"last_name":"Redchenko","full_name":"Redchenko, Elena","id":"2C21D6E8-F248-11E8-B48F-1D18A9856A87","first_name":"Elena"},{"first_name":"Matilda","id":"3F920B30-F248-11E8-B48F-1D18A9856A87","last_name":"Peruzzo","full_name":"Peruzzo, Matilda","orcid":"0000-0002-3415-4628"},{"first_name":"Matthias","id":"45598606-F248-11E8-B48F-1D18A9856A87","last_name":"Wulf","orcid":"0000-0001-6613-1378","full_name":"Wulf, Matthias"},{"last_name":"Lewis","full_name":"Lewis, Dylan","first_name":"Dylan"},{"full_name":"Arnold, Georg M","orcid":"0000-0003-1397-7876","last_name":"Arnold","first_name":"Georg M","id":"3770C838-F248-11E8-B48F-1D18A9856A87"},{"id":"4B591CBA-F248-11E8-B48F-1D18A9856A87","first_name":"Johannes M","full_name":"Fink, Johannes M","orcid":"0000-0001-8112-028X","last_name":"Fink"}],"article_processing_charge":"No","external_id":{"isi":["000472860000042"],"arxiv":["1809.05865"]}},{"day":"01","publication":"npj Quantum Information","has_accepted_license":"1","isi":1,"year":"2019","date_published":"2019-12-01T00:00:00Z","doi":"10.1038/s41534-019-0220-5","date_created":"2019-12-09T08:18:56Z","publisher":"Springer Nature","quality_controlled":"1","oa":1,"user_id":"c635000d-4b10-11ee-a964-aac5a93f6ac1","citation":{"mla":"Rueda Sanchez, Alfredo R., et al. “Electro-Optic Entanglement Source for Microwave to Telecom Quantum State Transfer.” Npj Quantum Information, vol. 5, 108, Springer Nature, 2019, doi:10.1038/s41534-019-0220-5.","apa":"Rueda Sanchez, A. R., Hease, W. J., Barzanjeh, S., & Fink, J. M. (2019). Electro-optic entanglement source for microwave to telecom quantum state transfer. Npj Quantum Information. Springer Nature. https://doi.org/10.1038/s41534-019-0220-5","ama":"Rueda Sanchez AR, Hease WJ, Barzanjeh S, Fink JM. Electro-optic entanglement source for microwave to telecom quantum state transfer. npj Quantum Information. 2019;5. doi:10.1038/s41534-019-0220-5","short":"A.R. Rueda Sanchez, W.J. Hease, S. Barzanjeh, J.M. Fink, Npj Quantum Information 5 (2019).","ieee":"A. R. Rueda Sanchez, W. J. Hease, S. Barzanjeh, and J. M. Fink, “Electro-optic entanglement source for microwave to telecom quantum state transfer,” npj Quantum Information, vol. 5. Springer Nature, 2019.","chicago":"Rueda Sanchez, Alfredo R, William J Hease, Shabir Barzanjeh, and Johannes M Fink. “Electro-Optic Entanglement Source for Microwave to Telecom Quantum State Transfer.” Npj Quantum Information. Springer Nature, 2019. https://doi.org/10.1038/s41534-019-0220-5.","ista":"Rueda Sanchez AR, Hease WJ, Barzanjeh S, Fink JM. 2019. Electro-optic entanglement source for microwave to telecom quantum state transfer. npj Quantum Information. 5, 108."},"title":"Electro-optic entanglement source for microwave to telecom quantum state transfer","author":[{"last_name":"Rueda Sanchez","full_name":"Rueda Sanchez, Alfredo R","orcid":"0000-0001-6249-5860","id":"3B82B0F8-F248-11E8-B48F-1D18A9856A87","first_name":"Alfredo R"},{"id":"29705398-F248-11E8-B48F-1D18A9856A87","first_name":"William J","last_name":"Hease","full_name":"Hease, William J","orcid":"0000-0001-9868-2166"},{"orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir","last_name":"Barzanjeh","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir"},{"last_name":"Fink","full_name":"Fink, Johannes M","orcid":"0000-0001-8112-028X","first_name":"Johannes M","id":"4B591CBA-F248-11E8-B48F-1D18A9856A87"}],"article_processing_charge":"No","external_id":{"isi":["000502996200003"],"arxiv":["1909.01470"]},"article_number":"108","project":[{"grant_number":"758053","name":"A Fiber Optic Transceiver for Superconducting Qubits","_id":"26336814-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"},{"_id":"258047B6-B435-11E9-9278-68D0E5697425","call_identifier":"H2020","name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics SUPEREOM","grant_number":"707438"},{"grant_number":"732894","name":"Hybrid Optomechanical Technologies","call_identifier":"H2020","_id":"257EB838-B435-11E9-9278-68D0E5697425"},{"call_identifier":"FWF","_id":"26927A52-B435-11E9-9278-68D0E5697425","name":"Integrating superconducting quantum circuits","grant_number":"F07105"}],"file":[{"content_type":"application/pdf","relation":"main_file","access_level":"open_access","checksum":"13e0ea1d4f9b5f5710780d9473364f58","file_id":"7157","file_size":1580132,"date_updated":"2020-07-14T12:47:50Z","creator":"dernst","file_name":"2019_NPJ_Rueda.pdf","date_created":"2019-12-09T08:25:06Z"}],"language":[{"iso":"eng"}],"publication_identifier":{"issn":["2056-6387"]},"publication_status":"published","volume":5,"ec_funded":1,"oa_version":"Published Version","abstract":[{"lang":"eng","text":"We propose an efficient microwave-photonic modulator as a resource for stationary entangled microwave-optical fields and develop the theory for deterministic entanglement generation and quantum state transfer in multi-resonant electro-optic systems. The device is based on a single crystal whispering gallery mode resonator integrated into a 3D-microwave cavity. The specific design relies on a new combination of thin-film technology and conventional machining that is optimized for the lowest dissipation rates in the microwave, optical, and mechanical domains. We extract important device properties from finite-element simulations and predict continuous variable entanglement generation rates on the order of a Mebit/s for optical pump powers of only a few tens of microwatts. We compare the quantum state transfer fidelities of coherent, squeezed, and non-Gaussian cat states for both teleportation and direct conversion protocols under realistic conditions. Combining the unique capabilities of circuit quantum electrodynamics with the resilience of fiber optic communication could facilitate long-distance solid-state qubit networks, new methods for quantum signal synthesis, quantum key distribution, and quantum enhanced detection, as well as more power-efficient classical sensing and modulation."}],"month":"12","intvolume":" 5","scopus_import":"1","ddc":["530"],"date_updated":"2023-09-06T11:22:39Z","file_date_updated":"2020-07-14T12:47:50Z","department":[{"_id":"JoFi"}],"_id":"7156","status":"public","article_type":"original","type":"journal_article","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","image":"/images/cc_by.png","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","short":"CC BY (4.0)"}},{"month":"03","intvolume":" 23","scopus_import":"1","main_file_link":[{"url":"https://www.bioscience.org/2018/v23/af/4651/fulltext.htm","open_access":"1"}],"pmid":1,"oa_version":"Submitted Version","abstract":[{"text":"In this paper, we discuss biological effects of electromagnetic (EM) fields in the context of cancer biology. In particular, we review the nanomechanical properties of microtubules (MTs), the latter being one of the most successful targets for cancer therapy. We propose an investigation on the coupling of electromagnetic radiation to mechanical vibrations of MTs as an important basis for biological and medical applications. In our opinion, optomechanical methods can accurately monitor and control the mechanical properties of isolated MTs in a liquid environment. Consequently, studying nanomechanical properties of MTs may give useful information for future applications to diagnostic and therapeutic technologies involving non-invasive externally applied physical fields. For example, electromagnetic fields or high intensity ultrasound can be used therapeutically avoiding harmful side effects of chemotherapeutic agents or classical radiation therapy.","lang":"eng"}],"issue":"8","volume":23,"ec_funded":1,"language":[{"iso":"eng"}],"publication_status":"published","status":"public","type":"journal_article","_id":"287","department":[{"_id":"JoFi"}],"date_updated":"2023-09-11T13:38:14Z","publisher":"Frontiers in Bioscience","quality_controlled":"1","oa":1,"acknowledgement":"The work of SB has been supported by the European Unions Horizon 2020 research and innovation program under the Marie Sklodowska Curie grant agreement No MSC-IF 707438 SUPEREOM. JAT gratefully acknowledges funding support from NSERC (Canada) for his research. MC acknowledges support from the Czech Science Foundation, projects 15-17102S and 17-11898S and he participates in COST Action BM1309, CA15211 and bilateral exchange project between Czech and Slovak Academies of Sciences, SAV-15-22.","doi":"10.2741/4651","date_published":"2018-03-01T00:00:00Z","date_created":"2018-12-11T11:45:37Z","page":"1391 - 1406","day":"01","publication":"Frontiers in Bioscience - Landmark","isi":1,"year":"2018","project":[{"call_identifier":"H2020","_id":"258047B6-B435-11E9-9278-68D0E5697425","name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics SUPEREOM","grant_number":"707438"}],"title":"Electromagnetic fields and optomechanics In cancer diagnostics and treatment","author":[{"full_name":"Salari, Vahid","last_name":"Salari","first_name":"Vahid"},{"id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir","full_name":"Barzanjeh, Shabir","orcid":"0000-0003-0415-1423","last_name":"Barzanjeh"},{"full_name":"Cifra, Michal","last_name":"Cifra","first_name":"Michal"},{"first_name":"Christoph","last_name":"Simon","full_name":"Simon, Christoph"},{"first_name":"Felix","last_name":"Scholkmann","full_name":"Scholkmann, Felix"},{"first_name":"Zahra","last_name":"Alirezaei","full_name":"Alirezaei, Zahra"},{"last_name":"Tuszynski","full_name":"Tuszynski, Jack","first_name":"Jack"}],"article_processing_charge":"No","external_id":{"pmid":["29293441"],"isi":["000439042800001"]},"user_id":"c635000d-4b10-11ee-a964-aac5a93f6ac1","citation":{"chicago":"Salari, Vahid, Shabir Barzanjeh, Michal Cifra, Christoph Simon, Felix Scholkmann, Zahra Alirezaei, and Jack Tuszynski. “Electromagnetic Fields and Optomechanics In Cancer Diagnostics and Treatment.” Frontiers in Bioscience - Landmark. Frontiers in Bioscience, 2018. https://doi.org/10.2741/4651.","ista":"Salari V, Barzanjeh S, Cifra M, Simon C, Scholkmann F, Alirezaei Z, Tuszynski J. 2018. Electromagnetic fields and optomechanics In cancer diagnostics and treatment. Frontiers in Bioscience - Landmark. 23(8), 1391–1406.","mla":"Salari, Vahid, et al. “Electromagnetic Fields and Optomechanics In Cancer Diagnostics and Treatment.” Frontiers in Bioscience - Landmark, vol. 23, no. 8, Frontiers in Bioscience, 2018, pp. 1391–406, doi:10.2741/4651.","apa":"Salari, V., Barzanjeh, S., Cifra, M., Simon, C., Scholkmann, F., Alirezaei, Z., & Tuszynski, J. (2018). Electromagnetic fields and optomechanics In cancer diagnostics and treatment. Frontiers in Bioscience - Landmark. Frontiers in Bioscience. https://doi.org/10.2741/4651","ama":"Salari V, Barzanjeh S, Cifra M, et al. Electromagnetic fields and optomechanics In cancer diagnostics and treatment. Frontiers in Bioscience - Landmark. 2018;23(8):1391-1406. doi:10.2741/4651","short":"V. Salari, S. Barzanjeh, M. Cifra, C. Simon, F. Scholkmann, Z. Alirezaei, J. Tuszynski, Frontiers in Bioscience - Landmark 23 (2018) 1391–1406.","ieee":"V. Salari et al., “Electromagnetic fields and optomechanics In cancer diagnostics and treatment,” Frontiers in Bioscience - Landmark, vol. 23, no. 8. Frontiers in Bioscience, pp. 1391–1406, 2018."}},{"quality_controlled":"1","publisher":"American Physical Society","oa":1,"day":"07","publication":"Physical Review Letters","isi":1,"year":"2018","date_published":"2018-02-07T00:00:00Z","doi":"10.1103/PhysRevLett.120.060601","date_created":"2018-12-11T11:46:28Z","article_number":"060601 ","project":[{"name":"Hybrid Optomechanical Technologies","grant_number":"732894","_id":"257EB838-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"},{"name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics SUPEREOM","grant_number":"707438","_id":"258047B6-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"}],"user_id":"c635000d-4b10-11ee-a964-aac5a93f6ac1","citation":{"chicago":"Barzanjeh, Shabir, Matteo Aquilina, and André Xuereb. “Manipulating the Flow of Thermal Noise in Quantum Devices.” Physical Review Letters. American Physical Society, 2018. https://doi.org/10.1103/PhysRevLett.120.060601.","ista":"Barzanjeh S, Aquilina M, Xuereb A. 2018. Manipulating the flow of thermal noise in quantum devices. Physical Review Letters. 120(6), 060601.","mla":"Barzanjeh, Shabir, et al. “Manipulating the Flow of Thermal Noise in Quantum Devices.” Physical Review Letters, vol. 120, no. 6, 060601, American Physical Society, 2018, doi:10.1103/PhysRevLett.120.060601.","ieee":"S. Barzanjeh, M. Aquilina, and A. Xuereb, “Manipulating the flow of thermal noise in quantum devices,” Physical Review Letters, vol. 120, no. 6. American Physical Society, 2018.","short":"S. Barzanjeh, M. Aquilina, A. Xuereb, Physical Review Letters 120 (2018).","apa":"Barzanjeh, S., Aquilina, M., & Xuereb, A. (2018). Manipulating the flow of thermal noise in quantum devices. Physical Review Letters. American Physical Society. https://doi.org/10.1103/PhysRevLett.120.060601","ama":"Barzanjeh S, Aquilina M, Xuereb A. Manipulating the flow of thermal noise in quantum devices. Physical Review Letters. 2018;120(6). doi:10.1103/PhysRevLett.120.060601"},"title":"Manipulating the flow of thermal noise in quantum devices","publist_id":"7387","author":[{"id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir","last_name":"Barzanjeh"},{"first_name":"Matteo","last_name":"Aquilina","full_name":"Aquilina, Matteo"},{"first_name":"André","full_name":"Xuereb, André","last_name":"Xuereb"}],"external_id":{"arxiv":["1706.09051"],"isi":["000424382100004"]},"article_processing_charge":"No","oa_version":"Preprint","abstract":[{"text":"There has been significant interest recently in using complex quantum systems to create effective nonreciprocal dynamics. Proposals have been put forward for the realization of artificial magnetic fields for photons and phonons; experimental progress is fast making these proposals a reality. Much work has concentrated on the use of such systems for controlling the flow of signals, e.g., to create isolators or directional amplifiers for optical signals. In this Letter, we build on this work but move in a different direction. We develop the theory of and discuss a potential realization for the controllable flow of thermal noise in quantum systems. We demonstrate theoretically that the unidirectional flow of thermal noise is possible within quantum cascaded systems. Viewing an optomechanical platform as a cascaded system we show here that one can ultimately control the direction of the flow of thermal noise. By appropriately engineering the mechanical resonator, which acts as an artificial reservoir, the flow of thermal noise can be constrained to a desired direction, yielding a thermal rectifier. The proposed quantum thermal noise rectifier could potentially be used to develop devices such as a thermal modulator, a thermal router, and a thermal amplifier for nanoelectronic devices and superconducting circuits.","lang":"eng"}],"month":"02","intvolume":" 120","scopus_import":"1","main_file_link":[{"open_access":"1","url":"https://arxiv.org/abs/1706.09051"}],"language":[{"iso":"eng"}],"publication_status":"published","related_material":{"link":[{"relation":"press_release","url":"https://ist.ac.at/en/news/interference-as-a-new-method-for-cooling-quantum-devices/","description":"News on IST Homepage"}]},"issue":"6","volume":120,"ec_funded":1,"_id":"436","status":"public","type":"journal_article","date_updated":"2023-09-13T08:52:27Z","department":[{"_id":"JoFi"}]},{"date_updated":"2023-09-18T08:12:24Z","department":[{"_id":"JoFi"}],"_id":"155","status":"public","conference":{"location":"Strasbourg, France","end_date":"2018-04-26","start_date":"2018-04-22","name":"SPIE: The international society for optical engineering"},"type":"conference","language":[{"iso":"eng"}],"publication_status":"published","volume":10672,"oa_version":"Preprint","abstract":[{"text":"There is currently significant interest in operating devices in the quantum regime, where their behaviour cannot be explained through classical mechanics. Quantum states, including entangled states, are fragile and easily disturbed by excessive thermal noise. Here we address the question of whether it is possible to create non-reciprocal devices that encourage the flow of thermal noise towards or away from a particular quantum device in a network. Our work makes use of the cascaded systems formalism to answer this question in the affirmative, showing how a three-port device can be used as an effective thermal transistor, and illustrates how this formalism maps onto an experimentally-realisable optomechanical system. Our results pave the way to more resilient quantum devices and to the use of thermal noise as a resource.","lang":"eng"}],"intvolume":" 10672","month":"05","main_file_link":[{"url":"https://arxiv.org/abs/1806.01000","open_access":"1"}],"alternative_title":["Proceedings of SPIE"],"scopus_import":"1","user_id":"c635000d-4b10-11ee-a964-aac5a93f6ac1","citation":{"mla":"Xuereb, André, et al. Routing Thermal Noise through Quantum Networks. Edited by D L Andrews et al., vol. 10672, 106721N, SPIE, 2018, doi:10.1117/12.2309928.","ama":"Xuereb A, Aquilina M, Barzanjeh S. Routing thermal noise through quantum networks. In: Andrews DL, Ostendorf A, Bain AJ, Nunzi JM, eds. Vol 10672. SPIE; 2018. doi:10.1117/12.2309928","apa":"Xuereb, A., Aquilina, M., & Barzanjeh, S. (2018). Routing thermal noise through quantum networks. In D. L. Andrews, A. Ostendorf, A. J. Bain, & J. M. Nunzi (Eds.) (Vol. 10672). Presented at the SPIE: The international society for optical engineering, Strasbourg, France: SPIE. https://doi.org/10.1117/12.2309928","short":"A. Xuereb, M. Aquilina, S. Barzanjeh, in:, D.L. Andrews, A. Ostendorf, A.J. Bain, J.M. Nunzi (Eds.), SPIE, 2018.","ieee":"A. Xuereb, M. Aquilina, and S. Barzanjeh, “Routing thermal noise through quantum networks,” presented at the SPIE: The international society for optical engineering, Strasbourg, France, 2018, vol. 10672.","chicago":"Xuereb, André, Matteo Aquilina, and Shabir Barzanjeh. “Routing Thermal Noise through Quantum Networks.” edited by D L Andrews, A Ostendorf, A J Bain, and J M Nunzi, Vol. 10672. SPIE, 2018. https://doi.org/10.1117/12.2309928.","ista":"Xuereb A, Aquilina M, Barzanjeh S. 2018. Routing thermal noise through quantum networks. SPIE: The international society for optical engineering, Proceedings of SPIE, vol. 10672, 106721N."},"editor":[{"full_name":"Andrews, D L","last_name":"Andrews","first_name":"D L"},{"first_name":"A","last_name":"Ostendorf","full_name":"Ostendorf, A"},{"first_name":"A J","full_name":"Bain, A J","last_name":"Bain"},{"last_name":"Nunzi","full_name":"Nunzi, J M","first_name":"J M"}],"title":"Routing thermal noise through quantum networks","external_id":{"isi":["000453298500019"],"arxiv":["1806.01000"]},"article_processing_charge":"No","author":[{"first_name":"André","full_name":"Xuereb, André","last_name":"Xuereb"},{"first_name":"Matteo","last_name":"Aquilina","full_name":"Aquilina, Matteo"},{"last_name":"Barzanjeh","full_name":"Barzanjeh, Shabir","orcid":"0000-0003-0415-1423","first_name":"Shabir","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87"}],"publist_id":"7766","article_number":"106721N","day":"04","year":"2018","isi":1,"date_created":"2018-12-11T11:44:55Z","doi":"10.1117/12.2309928","date_published":"2018-05-04T00:00:00Z","oa":1,"quality_controlled":"1","publisher":"SPIE"},{"year":"2017","publication":" Physical Review E Statistical Nonlinear and Soft Matter Physics ","day":"12","date_created":"2018-12-11T11:48:00Z","doi":"10.1103/PhysRevE.96.012404","date_published":"2017-07-12T00:00:00Z","oa":1,"quality_controlled":"1","publisher":"American Institute of Physics","citation":{"short":"S. Barzanjeh, V. Salari, J. Tuszynski, M. Cifra, C. Simon, Physical Review E Statistical Nonlinear and Soft Matter Physics 96 (2017).","ieee":"S. Barzanjeh, V. Salari, J. Tuszynski, M. Cifra, and C. Simon, “Optomechanical proposal for monitoring microtubule mechanical vibrations,” Physical Review E Statistical Nonlinear and Soft Matter Physics , vol. 96, no. 1. American Institute of Physics, 2017.","apa":"Barzanjeh, S., Salari, V., Tuszynski, J., Cifra, M., & Simon, C. (2017). Optomechanical proposal for monitoring microtubule mechanical vibrations. Physical Review E Statistical Nonlinear and Soft Matter Physics . American Institute of Physics. https://doi.org/10.1103/PhysRevE.96.012404","ama":"Barzanjeh S, Salari V, Tuszynski J, Cifra M, Simon C. Optomechanical proposal for monitoring microtubule mechanical vibrations. Physical Review E Statistical Nonlinear and Soft Matter Physics . 2017;96(1). doi:10.1103/PhysRevE.96.012404","mla":"Barzanjeh, Shabir, et al. “Optomechanical Proposal for Monitoring Microtubule Mechanical Vibrations.” Physical Review E Statistical Nonlinear and Soft Matter Physics , vol. 96, no. 1, 012404, American Institute of Physics, 2017, doi:10.1103/PhysRevE.96.012404.","ista":"Barzanjeh S, Salari V, Tuszynski J, Cifra M, Simon C. 2017. Optomechanical proposal for monitoring microtubule mechanical vibrations. Physical Review E Statistical Nonlinear and Soft Matter Physics . 96(1), 012404.","chicago":"Barzanjeh, Shabir, Vahid Salari, Jack Tuszynski, Michal Cifra, and Christoph Simon. “Optomechanical Proposal for Monitoring Microtubule Mechanical Vibrations.” Physical Review E Statistical Nonlinear and Soft Matter Physics . American Institute of Physics, 2017. https://doi.org/10.1103/PhysRevE.96.012404."},"user_id":"3E5EF7F0-F248-11E8-B48F-1D18A9856A87","publist_id":"6997","author":[{"first_name":"Shabir","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","last_name":"Barzanjeh","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir"},{"full_name":"Salari, Vahid","last_name":"Salari","first_name":"Vahid"},{"last_name":"Tuszynski","full_name":"Tuszynski, Jack","first_name":"Jack"},{"first_name":"Michal","full_name":"Cifra, Michal","last_name":"Cifra"},{"last_name":"Simon","full_name":"Simon, Christoph","first_name":"Christoph"}],"title":"Optomechanical proposal for monitoring microtubule mechanical vibrations","article_number":"012404","project":[{"call_identifier":"H2020","_id":"258047B6-B435-11E9-9278-68D0E5697425","name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics","grant_number":"707438"}],"publication_status":"published","publication_identifier":{"issn":["24700045"]},"language":[{"iso":"eng"}],"ec_funded":1,"volume":96,"issue":"1","abstract":[{"lang":"eng","text":"Microtubules provide the mechanical force required for chromosome separation during mitosis. However, little is known about the dynamic (high-frequency) mechanical properties of microtubules. Here, we theoretically propose to control the vibrations of a doubly clamped microtubule by tip electrodes and to detect its motion via the optomechanical coupling between the vibrational modes of the microtubule and an optical cavity. In the presence of a red-detuned strong pump laser, this coupling leads to optomechanical-induced transparency of an optical probe field, which can be detected with state-of-the art technology. The center frequency and line width of the transparency peak give the resonance frequency and damping rate of the microtubule, respectively, while the height of the peak reveals information about the microtubule-cavity field coupling. Our method opens the new possibilities to gain information about the physical properties of microtubules, which will enhance our capability to design physical cancer treatment protocols as alternatives to chemotherapeutic drugs."}],"oa_version":"Submitted Version","main_file_link":[{"url":"https://arxiv.org/pdf/1612.07061.pdf","open_access":"1"}],"scopus_import":1,"intvolume":" 96","month":"07","date_updated":"2023-02-23T12:56:35Z","department":[{"_id":"JoFi"}],"_id":"700","type":"journal_article","status":"public"},{"date_published":"2017-10-16T00:00:00Z","doi":"10.1038/s41467-017-01304-x","date_created":"2018-12-11T11:48:33Z","has_accepted_license":"1","isi":1,"year":"2017","day":"16","publication":"Nature Communications","publisher":"Nature Publishing Group","quality_controlled":"1","oa":1,"author":[{"id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir","last_name":"Barzanjeh","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir"},{"first_name":"Matthias","id":"45598606-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0001-6613-1378","full_name":"Wulf, Matthias","last_name":"Wulf"},{"first_name":"Matilda","id":"3F920B30-F248-11E8-B48F-1D18A9856A87","full_name":"Peruzzo, Matilda","orcid":"0000-0002-3415-4628","last_name":"Peruzzo"},{"first_name":"Mahmoud","last_name":"Kalaee","full_name":"Kalaee, Mahmoud"},{"last_name":"Dieterle","full_name":"Dieterle, Paul","first_name":"Paul"},{"last_name":"Painter","full_name":"Painter, Oskar","first_name":"Oskar"},{"orcid":"0000-0001-8112-028X","full_name":"Fink, Johannes M","last_name":"Fink","first_name":"Johannes M","id":"4B591CBA-F248-11E8-B48F-1D18A9856A87"}],"publist_id":"6855","external_id":{"isi":["000412999700021"]},"article_processing_charge":"Yes (in subscription journal)","title":"Mechanical on chip microwave circulator","citation":{"ama":"Barzanjeh S, Wulf M, Peruzzo M, et al. Mechanical on chip microwave circulator. Nature Communications. 2017;8(1). doi:10.1038/s41467-017-01304-x","apa":"Barzanjeh, S., Wulf, M., Peruzzo, M., Kalaee, M., Dieterle, P., Painter, O., & Fink, J. M. (2017). Mechanical on chip microwave circulator. Nature Communications. Nature Publishing Group. https://doi.org/10.1038/s41467-017-01304-x","ieee":"S. Barzanjeh et al., “Mechanical on chip microwave circulator,” Nature Communications, vol. 8, no. 1. Nature Publishing Group, 2017.","short":"S. Barzanjeh, M. Wulf, M. Peruzzo, M. Kalaee, P. Dieterle, O. Painter, J.M. Fink, Nature Communications 8 (2017).","mla":"Barzanjeh, Shabir, et al. “Mechanical on Chip Microwave Circulator.” Nature Communications, vol. 8, no. 1, 1304, Nature Publishing Group, 2017, doi:10.1038/s41467-017-01304-x.","ista":"Barzanjeh S, Wulf M, Peruzzo M, Kalaee M, Dieterle P, Painter O, Fink JM. 2017. Mechanical on chip microwave circulator. Nature Communications. 8(1), 1304.","chicago":"Barzanjeh, Shabir, Matthias Wulf, Matilda Peruzzo, Mahmoud Kalaee, Paul Dieterle, Oskar Painter, and Johannes M Fink. “Mechanical on Chip Microwave Circulator.” Nature Communications. Nature Publishing Group, 2017. https://doi.org/10.1038/s41467-017-01304-x."},"user_id":"c635000d-4b10-11ee-a964-aac5a93f6ac1","project":[{"name":"Hybrid Optomechanical Technologies","grant_number":"732894","call_identifier":"H2020","_id":"257EB838-B435-11E9-9278-68D0E5697425"},{"name":"Microwave-to-Optical Quantum Link: Quantum Teleportation and Quantum Illumination with cavity Optomechanics","grant_number":"707438","call_identifier":"H2020","_id":"258047B6-B435-11E9-9278-68D0E5697425"}],"article_number":"1304","issue":"1","volume":8,"ec_funded":1,"publication_identifier":{"issn":["20411723"]},"publication_status":"published","file":[{"date_updated":"2020-07-14T12:48:06Z","file_size":1467696,"creator":"system","date_created":"2018-12-12T10:15:25Z","file_name":"IST-2017-867-v1+1_s41467-017-01304-x.pdf","content_type":"application/pdf","access_level":"open_access","relation":"main_file","checksum":"b68dafa71d1834c23b742cd9987a3d5f","file_id":"5145"}],"language":[{"iso":"eng"}],"scopus_import":"1","month":"10","intvolume":" 8","abstract":[{"text":"Nonreciprocal circuit elements form an integral part of modern measurement and communication systems. Mathematically they require breaking of time-reversal symmetry, typically achieved using magnetic materials and more recently using the quantum Hall effect, parametric permittivity modulation or Josephson nonlinearities. Here we demonstrate an on-chip magnetic-free circulator based on reservoir-engineered electromechanic interactions. Directional circulation is achieved with controlled phase-sensitive interference of six distinct electro-mechanical signal conversion paths. The presented circulator is compact, its silicon-on-insulator platform is compatible with both superconducting qubits and silicon photonics, and its noise performance is close to the quantum limit. With a high dynamic range, a tunable bandwidth of up to 30 MHz and an in situ reconfigurability as beam splitter or wavelength converter, it could pave the way for superconducting qubit processors with multiplexed on-chip signal processing and readout.","lang":"eng"}],"oa_version":"Published Version","department":[{"_id":"JoFi"}],"file_date_updated":"2020-07-14T12:48:06Z","date_updated":"2023-09-27T12:11:28Z","ddc":["539"],"type":"journal_article","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","image":"/images/cc_by.png","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","short":"CC BY (4.0)"},"status":"public","pubrep_id":"867","_id":"798"},{"abstract":[{"text":"We present a microelectromechanical system, in which a silicon beam is attached to a comb-drive\r\nactuator, which is used to tune the tension in the silicon beam and thus its resonance frequency. By\r\nmeasuring the resonance frequencies of the system, we show that the comb-drive actuator and the\r\nsilicon beam behave as two strongly coupled resonators. Interestingly, the effective coupling rate\r\n(1.5 MHz) is tunable with the comb-drive actuator (10%) as well as with a side-gate (10%)\r\nplaced close to the silicon beam. In contrast, the effective spring constant of the system is insensitive\r\nto either of them and changes only by 60.5%. Finally, we show that the comb-drive actuator\r\ncan be used to switch between different coupling rates with a frequency of at least 10 kHz.\r\n","lang":"eng"}],"acknowledgement":"We acknowledge the support from the Helmholtz Nanoelectronic Facility (HNF) and funding from the ERC (GA-Nr. 280140).","oa_version":"Preprint","main_file_link":[{"url":"https://arxiv.org/abs/1607.04406","open_access":"1"}],"oa":1,"publisher":"American Institute of Physics","quality_controlled":"1","scopus_import":1,"intvolume":" 109","month":"10","publication_status":"published","year":"2016","language":[{"iso":"eng"}],"publication":"Applied Physics Letter","day":"04","date_created":"2018-12-11T11:51:28Z","doi":"10.1063/1.4964122","volume":109,"date_published":"2016-10-04T00:00:00Z","_id":"1339","article_number":"143507","type":"journal_article","status":"public","date_updated":"2023-02-21T10:35:06Z","citation":{"ista":"Verbiest G, Xu D, Goldsche M, Khodkov T, Barzanjeh S, Von Den Driesch N, Buca D, Stampfer C. 2016. Tunable mechanical coupling between driven microelectromechanical resonators. Applied Physics Letter. 109, 143507.","chicago":"Verbiest, Gerard, Duo Xu, Matthias Goldsche, Timofiy Khodkov, Shabir Barzanjeh, Nils Von Den Driesch, Dan Buca, and Christoph Stampfer. “Tunable Mechanical Coupling between Driven Microelectromechanical Resonators.” Applied Physics Letter. American Institute of Physics, 2016. https://doi.org/10.1063/1.4964122.","apa":"Verbiest, G., Xu, D., Goldsche, M., Khodkov, T., Barzanjeh, S., Von Den Driesch, N., … Stampfer, C. (2016). Tunable mechanical coupling between driven microelectromechanical resonators. Applied Physics Letter. American Institute of Physics. https://doi.org/10.1063/1.4964122","ama":"Verbiest G, Xu D, Goldsche M, et al. Tunable mechanical coupling between driven microelectromechanical resonators. Applied Physics Letter. 2016;109. doi:10.1063/1.4964122","short":"G. Verbiest, D. Xu, M. Goldsche, T. Khodkov, S. Barzanjeh, N. Von Den Driesch, D. Buca, C. Stampfer, Applied Physics Letter 109 (2016).","ieee":"G. Verbiest et al., “Tunable mechanical coupling between driven microelectromechanical resonators,” Applied Physics Letter, vol. 109. American Institute of Physics, 2016.","mla":"Verbiest, Gerard, et al. “Tunable Mechanical Coupling between Driven Microelectromechanical Resonators.” Applied Physics Letter, vol. 109, 143507, American Institute of Physics, 2016, doi:10.1063/1.4964122."},"user_id":"3E5EF7F0-F248-11E8-B48F-1D18A9856A87","author":[{"first_name":"Gerard","full_name":"Verbiest, Gerard","last_name":"Verbiest"},{"first_name":"Duo","id":"3454D55E-F248-11E8-B48F-1D18A9856A87","last_name":"Xu","full_name":"Xu, Duo"},{"last_name":"Goldsche","full_name":"Goldsche, Matthias","first_name":"Matthias"},{"last_name":"Khodkov","full_name":"Khodkov, Timofiy","first_name":"Timofiy"},{"orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir","last_name":"Barzanjeh","id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir"},{"last_name":"Von Den Driesch","full_name":"Von Den Driesch, Nils","first_name":"Nils"},{"first_name":"Dan","full_name":"Buca, Dan","last_name":"Buca"},{"full_name":"Stampfer, Christoph","last_name":"Stampfer","first_name":"Christoph"}],"publist_id":"5928","title":"Tunable mechanical coupling between driven microelectromechanical resonators","department":[{"_id":"JoFi"}]},{"title":"Phonon Josephson junction with nanomechanical resonators","author":[{"id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","first_name":"Shabir","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir","last_name":"Barzanjeh"},{"last_name":"Vitali","full_name":"Vitali, David","first_name":"David"}],"publist_id":"5841","user_id":"3E5EF7F0-F248-11E8-B48F-1D18A9856A87","citation":{"chicago":"Barzanjeh, Shabir, and David Vitali. “Phonon Josephson Junction with Nanomechanical Resonators.” Physical Review A - Atomic, Molecular, and Optical Physics. American Physical Society, 2016. https://doi.org/10.1103/PhysRevA.93.033846.","ista":"Barzanjeh S, Vitali D. 2016. Phonon Josephson junction with nanomechanical resonators. Physical Review A - Atomic, Molecular, and Optical Physics. 93(3), 033846.","mla":"Barzanjeh, Shabir, and David Vitali. “Phonon Josephson Junction with Nanomechanical Resonators.” Physical Review A - Atomic, Molecular, and Optical Physics, vol. 93, no. 3, 033846, American Physical Society, 2016, doi:10.1103/PhysRevA.93.033846.","ama":"Barzanjeh S, Vitali D. Phonon Josephson junction with nanomechanical resonators. Physical Review A - Atomic, Molecular, and Optical Physics. 2016;93(3). doi:10.1103/PhysRevA.93.033846","apa":"Barzanjeh, S., & Vitali, D. (2016). Phonon Josephson junction with nanomechanical resonators. Physical Review A - Atomic, Molecular, and Optical Physics. American Physical Society. https://doi.org/10.1103/PhysRevA.93.033846","ieee":"S. Barzanjeh and D. Vitali, “Phonon Josephson junction with nanomechanical resonators,” Physical Review A - Atomic, Molecular, and Optical Physics, vol. 93, no. 3. American Physical Society, 2016.","short":"S. Barzanjeh, D. Vitali, Physical Review A - Atomic, Molecular, and Optical Physics 93 (2016)."},"article_number":"033846","date_created":"2018-12-11T11:51:38Z","doi":"10.1103/PhysRevA.93.033846","date_published":"2016-03-28T00:00:00Z","publication":"Physical Review A - Atomic, Molecular, and Optical Physics","day":"28","year":"2016","oa":1,"publisher":"American Physical Society","quality_controlled":"1","acknowledgement":"The work of S.B. has been supported by the European Commission (Belgium) via the SCALEQIT program and by the Alexander von Humboldt Foundation. ","department":[{"_id":"JoFi"}],"date_updated":"2023-02-21T10:36:32Z","status":"public","type":"journal_article","_id":"1370","volume":93,"issue":"3","language":[{"iso":"eng"}],"publication_status":"published","intvolume":" 93","month":"03","main_file_link":[{"url":"http://arxiv.org/abs/1601.01818","open_access":"1"}],"scopus_import":1,"oa_version":"Preprint","abstract":[{"lang":"eng","text":"We study coherent phonon oscillations and tunneling between two coupled nonlinear nanomechanical resonators. We show that the coupling between two nanomechanical resonators creates an effective phonon Josephson junction, which exhibits two different dynamical behaviors: Josephson oscillation (phonon-Rabi oscillation) and macroscopic self-trapping (phonon blockade). Self-trapping originates from mechanical nonlinearities, meaning that when the nonlinearity exceeds its critical value, the energy exchange between the two resonators is suppressed, and phonon Josephson oscillations between them are completely blocked. An effective classical Hamiltonian for the phonon Josephson junction is derived and its mean-field dynamics is studied in phase space. Finally, we study the phonon-phonon coherence quantified by the mean fringe visibility, and show that the interaction between the two resonators may lead to the loss of coherence in the phononic junction."}]}]