Hybrid Integration of Silicon Photonic Devices on Lithium Niobate for Optomechanical Wavelength Conversion.
Hybrid integrated devices
hybrid photonics
optomechanics
pick-and-place
slapping
wavelength conversion
Journal
Nano letters
ISSN: 1530-6992
Titre abrégé: Nano Lett
Pays: United States
ID NLM: 101088070
Informations de publication
Date de publication:
13 Jan 2021
13 Jan 2021
Historique:
pubmed:
5
1
2021
medline:
5
1
2021
entrez:
4
1
2021
Statut:
ppublish
Résumé
The rapid development of quantum information processors has accelerated the demand for technologies that enable quantum networking. One promising approach uses mechanical resonators as an intermediary between microwave and optical fields. Signals from a superconducting, topological, or spin qubit processor can then be converted coherently to optical states at telecom wavelengths. However, current devices built from homogeneous structures suffer from added noise and a small conversion efficiency. Combining advantageous properties of different materials into a heterogeneous design should allow for superior quantum transduction devices-so far these hybrid approaches have however been hampered by complex fabrication procedures. Here we present a novel integration method, based on previous pick-and-place ideas, that can combine independently fabricated device components of different materials into a single device. The method allows for a precision alignment by continuous optical monitoring during the process. Using our method, we assemble a hybrid silicon-lithium niobate device with state-of-the-art wavelength conversion characteristics.
Identifiants
pubmed: 33393311
doi: 10.1021/acs.nanolett.0c03980
pmc: PMC7809686
doi:
Types de publication
Journal Article
Langues
eng
Sous-ensembles de citation
IM
Pagination
529-535Références
Nature. 2011 Jun 2;474(7349):64-7
pubmed: 21552277
Nano Lett. 2010 Oct 13;10(10):3922-6
pubmed: 20825160
Nat Commun. 2015 Jan 09;6:5873
pubmed: 25575346
Nat Commun. 2020 Jun 26;11(1):3237
pubmed: 32591510
Nature. 2020 Jul;583(7815):226-231
pubmed: 32641812
Nat Commun. 2020 Mar 30;11(1):1605
pubmed: 32231204
Nature. 2016 Feb 18;530(7590):313-6
pubmed: 26779950
Nano Lett. 2013;13(12):5791-6
pubmed: 24156318
Nature. 2019 Jul;571(7766):537-540
pubmed: 31341303
Science. 2013 Jun 7;340(6137):1202-5
pubmed: 23618764
Nature. 2011 Dec 8;480(7376):193-9
pubmed: 22158243
Science. 2017 Oct 13;358(6360):199-202
pubmed: 28935771
Nature. 2011 Oct 05;478(7367):89-92
pubmed: 21979049
Science. 2018 Oct 19;362(6412):
pubmed: 30337383
Nature. 2018 Nov;563(7733):661-665
pubmed: 30464339
Nature. 2020 Apr;580(7802):201-204
pubmed: 32269343
Nat Photonics. 2016 May;10(5):346-352
pubmed: 27446234
Nano Lett. 2016 Apr 13;16(4):2289-94
pubmed: 26954298
Nature. 2020 Dec;588(7839):599-603
pubmed: 33361793
Nat Commun. 2020 Sep 8;11(1):4460
pubmed: 32901014
Nature. 2008 Jun 19;453(7198):1023-30
pubmed: 18563153
Rev Sci Instrum. 2011 Jul;82(7):073709
pubmed: 21806191
Opt Express. 2016 Mar 21;24(6):5876-85
pubmed: 27136784
Nat Commun. 2020 Mar 3;11(1):1166
pubmed: 32127538
Rep Prog Phys. 2017 Oct;80(10):106001
pubmed: 28682303
Phys Rev Lett. 2018 Jun 15;120(24):243601
pubmed: 29956997
Nano Lett. 2017 Dec 13;17(12):7394-7400
pubmed: 29131963
Nature. 2014 Mar 6;507(7490):81-5
pubmed: 24598636