Feasibility study on superconducting carbon nanotubes coupled to microwave cavities

Research output: Contribution to conferencePosterScientific

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Feasibility study on superconducting carbon nanotubes coupled to microwave cavities. / Will, Marco; Kaikkonen, Jukka-Pekka; Hakonen, Pertti J.; Thanniyil Sebastian, Abhilash; Golubev, Dmitry.

2018. Poster session presented at Frontiers of Circuit QED and Optomechanics, Vienna, Austria.

Research output: Contribution to conferencePosterScientific

Harvard

Will, M, Kaikkonen, J-P, Hakonen, PJ, Thanniyil Sebastian, A & Golubev, D 2018, 'Feasibility study on superconducting carbon nanotubes coupled to microwave cavities' Frontiers of Circuit QED and Optomechanics, Vienna, Austria, 12/02/2018 - 14/02/2018, .

APA

Will, M., Kaikkonen, J-P., Hakonen, P. J., Thanniyil Sebastian, A., & Golubev, D. (2018). Feasibility study on superconducting carbon nanotubes coupled to microwave cavities. Poster session presented at Frontiers of Circuit QED and Optomechanics, Vienna, Austria.

Vancouver

Will M, Kaikkonen J-P, Hakonen PJ, Thanniyil Sebastian A, Golubev D. Feasibility study on superconducting carbon nanotubes coupled to microwave cavities. 2018. Poster session presented at Frontiers of Circuit QED and Optomechanics, Vienna, Austria.

Author

Will, Marco ; Kaikkonen, Jukka-Pekka ; Hakonen, Pertti J. ; Thanniyil Sebastian, Abhilash ; Golubev, Dmitry. / Feasibility study on superconducting carbon nanotubes coupled to microwave cavities. Poster session presented at Frontiers of Circuit QED and Optomechanics, Vienna, Austria.

Bibtex - Download

@conference{5daae3b9c7d64af390c68f3c70f99cb0,
title = "Feasibility study on superconducting carbon nanotubes coupled to microwave cavities",
abstract = "Utilizing the ultra-high sensitivity of a superconducting carbon nanotube (CNT) sensor to probe the quantum ground state is a promising approach. However, reproducible and reliable fabrication of such devices is still to be shown due to the demands on high temperature stable materials that the CNT growth requires and the crucial role the contact resistance plays for inducing superconductivity into the CNT. We approach the challenge with the molybdenum rhenium (MoRe) microwave cavity, which withstands high temperatures. Additionally we use a thin layer of palladium to improve contact resistance to the CNT. We conrm our measurements of the critical current through the Josephson junction with calculations.",
keywords = "FCQO18, Nano",
author = "Marco Will and Jukka-Pekka Kaikkonen and Hakonen, {Pertti J.} and {Thanniyil Sebastian}, Abhilash and Dmitry Golubev",
year = "2018",
month = "2",
day = "12",
language = "English",
note = "Frontiers of Circuit QED and Optomechanics, FCQO ; Conference date: 12-02-2018 Through 14-02-2018",
url = "https://ist.ac.at/fcqo18/welcome/",

}

RIS - Download

TY - CONF

T1 - Feasibility study on superconducting carbon nanotubes coupled to microwave cavities

AU - Will, Marco

AU - Kaikkonen, Jukka-Pekka

AU - Hakonen, Pertti J.

AU - Thanniyil Sebastian, Abhilash

AU - Golubev, Dmitry

PY - 2018/2/12

Y1 - 2018/2/12

N2 - Utilizing the ultra-high sensitivity of a superconducting carbon nanotube (CNT) sensor to probe the quantum ground state is a promising approach. However, reproducible and reliable fabrication of such devices is still to be shown due to the demands on high temperature stable materials that the CNT growth requires and the crucial role the contact resistance plays for inducing superconductivity into the CNT. We approach the challenge with the molybdenum rhenium (MoRe) microwave cavity, which withstands high temperatures. Additionally we use a thin layer of palladium to improve contact resistance to the CNT. We conrm our measurements of the critical current through the Josephson junction with calculations.

AB - Utilizing the ultra-high sensitivity of a superconducting carbon nanotube (CNT) sensor to probe the quantum ground state is a promising approach. However, reproducible and reliable fabrication of such devices is still to be shown due to the demands on high temperature stable materials that the CNT growth requires and the crucial role the contact resistance plays for inducing superconductivity into the CNT. We approach the challenge with the molybdenum rhenium (MoRe) microwave cavity, which withstands high temperatures. Additionally we use a thin layer of palladium to improve contact resistance to the CNT. We conrm our measurements of the critical current through the Josephson junction with calculations.

KW - FCQO18

KW - Nano

M3 - Poster

ER -

ID: 27525914