Sub-[Formula Omitted] Josephson Junctions for Superconducting Quantum Devices

For high-performance superconducting quantum devices based on Josephson junctions (JJs), decreasing lateral sizes is of great importance. Fabrication of sub-[Formula Omitted] JJs is challenging, due to nonflat surfaces with step heights of up to several 100 nm generated during the fabrication proces...

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Veröffentlicht in:	IEEE transactions on applied superconductivity 2013-06, Vol.23 (3), p.1100504-1100504
Hauptverfasser:	Meckbach, J. M, Merker, M, Buehler, S. J, Ilin, K, Neumeier, B, Kienzle, U, Goldobin, E, Kleiner, R, Koelle, D, Siegel, M
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Sprache:	eng
Schlagworte:	Density Devices Electron beam lithography Josephson junctions Multilayers Photolithography Qubits (quantum computing) Superconductivity
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container_title	IEEE transactions on applied superconductivity
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creator	Meckbach, J. M Merker, M Buehler, S. J Ilin, K Neumeier, B Kienzle, U Goldobin, E Kleiner, R Koelle, D Siegel, M
description	For high-performance superconducting quantum devices based on Josephson junctions (JJs), decreasing lateral sizes is of great importance. Fabrication of sub-[Formula Omitted] JJs is challenging, due to nonflat surfaces with step heights of up to several 100 nm generated during the fabrication process. We have refined a fabrication process with significantly decreased film thicknesses, resulting in almost flat surfaces at intermediate steps during the JJ definition. In combination with a mix-and-match process, combining electron-beam lithography and conventional photolithography, we can fabricate JJs with lateral dimensions down to 0.023 [Formula Omitted]. We propose this refined process as an alternative to the commonly used chemical-mechanical polishing procedure. Transport measurements of JJs, having critical-current densities ranging from 50 to 10[Formula Omitted], are presented at 4.2 K. Our JJ process yields excellent quality parameters, [Formula Omitted] up to [Formula Omitted]50, [Formula Omitted] from 15 to 80 mV and [Formula Omitted] up to 2.81 mV, and also allows the fabrication of high-quality, sub-[Formula Omitted] wide, long JJs (LJJs) for the study of Josephson vortex behavior. The developed technique can also be used for similar multilayer processes and is very promising for fabricating sub- [Formula Omitted] JJs for quantum devices such as SQUIDs, qubits, and SIS mixers.
doi_str_mv	10.1109/TASC.2012.2231719
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We propose this refined process as an alternative to the commonly used chemical-mechanical polishing procedure. Transport measurements of JJs, having critical-current densities ranging from 50 to 10[Formula Omitted], are presented at 4.2 K. Our JJ process yields excellent quality parameters, [Formula Omitted] up to [Formula Omitted]50, [Formula Omitted] from 15 to 80 mV and [Formula Omitted] up to 2.81 mV, and also allows the fabrication of high-quality, sub-[Formula Omitted] wide, long JJs (LJJs) for the study of Josephson vortex behavior. The developed technique can also be used for similar multilayer processes and is very promising for fabricating sub- [Formula Omitted] JJs for quantum devices such as SQUIDs, qubits, and SIS mixers.</description><identifier>ISSN: 1051-8223</identifier><identifier>EISSN: 1558-2515</identifier><identifier>DOI: 10.1109/TASC.2012.2231719</identifier><language>eng</language><publisher>New York: The Institute of Electrical and Electronics Engineers, Inc. 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In combination with a mix-and-match process, combining electron-beam lithography and conventional photolithography, we can fabricate JJs with lateral dimensions down to 0.023 [Formula Omitted]. We propose this refined process as an alternative to the commonly used chemical-mechanical polishing procedure. Transport measurements of JJs, having critical-current densities ranging from 50 to 10[Formula Omitted], are presented at 4.2 K. Our JJ process yields excellent quality parameters, [Formula Omitted] up to [Formula Omitted]50, [Formula Omitted] from 15 to 80 mV and [Formula Omitted] up to 2.81 mV, and also allows the fabrication of high-quality, sub-[Formula Omitted] wide, long JJs (LJJs) for the study of Josephson vortex behavior. 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J</au><au>Ilin, K</au><au>Neumeier, B</au><au>Kienzle, U</au><au>Goldobin, E</au><au>Kleiner, R</au><au>Koelle, D</au><au>Siegel, M</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Sub-[Formula Omitted] Josephson Junctions for Superconducting Quantum Devices</atitle><jtitle>IEEE transactions on applied superconductivity</jtitle><date>2013-06-01</date><risdate>2013</risdate><volume>23</volume><issue>3</issue><spage>1100504</spage><epage>1100504</epage><pages>1100504-1100504</pages><issn>1051-8223</issn><eissn>1558-2515</eissn><abstract>For high-performance superconducting quantum devices based on Josephson junctions (JJs), decreasing lateral sizes is of great importance. Fabrication of sub-[Formula Omitted] JJs is challenging, due to nonflat surfaces with step heights of up to several 100 nm generated during the fabrication process. We have refined a fabrication process with significantly decreased film thicknesses, resulting in almost flat surfaces at intermediate steps during the JJ definition. In combination with a mix-and-match process, combining electron-beam lithography and conventional photolithography, we can fabricate JJs with lateral dimensions down to 0.023 [Formula Omitted]. We propose this refined process as an alternative to the commonly used chemical-mechanical polishing procedure. Transport measurements of JJs, having critical-current densities ranging from 50 to 10[Formula Omitted], are presented at 4.2 K. Our JJ process yields excellent quality parameters, [Formula Omitted] up to [Formula Omitted]50, [Formula Omitted] from 15 to 80 mV and [Formula Omitted] up to 2.81 mV, and also allows the fabrication of high-quality, sub-[Formula Omitted] wide, long JJs (LJJs) for the study of Josephson vortex behavior. 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subjects	Density Devices Electron beam lithography Josephson junctions Multilayers Photolithography Qubits (quantum computing) Superconductivity
title	Sub-[Formula Omitted] Josephson Junctions for Superconducting Quantum Devices
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