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Nuclear demagnetisation cooling of a nanoelectronic device

Research output: Contribution to Journal/MagazineMeeting abstract

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Nuclear demagnetisation cooling of a nanoelectronic device. / Jones, Alex; Bradley, Ian; Guénault, Tony et al.
In: APS March Meeting 2017, 2017.

Research output: Contribution to Journal/MagazineMeeting abstract

Harvard

Jones, A, Bradley, I, Guénault, T, Gunnarsson, D, Haley, R, Holt, S, Pashkin, Y, Penttilä, J, Prance, J, Prunnila, M & Roschier, L 2017, 'Nuclear demagnetisation cooling of a nanoelectronic device', APS March Meeting 2017. <http://adsabs.harvard.edu/abs/2017APS..MARB36014J>

APA

Jones, A., Bradley, I., Guénault, T., Gunnarsson, D., Haley, R., Holt, S., Pashkin, Y., Penttilä, J., Prance, J., Prunnila, M., & Roschier, L. (2017). Nuclear demagnetisation cooling of a nanoelectronic device. APS March Meeting 2017. http://adsabs.harvard.edu/abs/2017APS..MARB36014J

Vancouver

Jones A, Bradley I, Guénault T, Gunnarsson D, Haley R, Holt S et al. Nuclear demagnetisation cooling of a nanoelectronic device. APS March Meeting 2017. 2017.

Author

Jones, Alex ; Bradley, Ian ; Guénault, Tony et al. / Nuclear demagnetisation cooling of a nanoelectronic device. In: APS March Meeting 2017. 2017.

Bibtex

@article{ab6bcd3b1af2442d89f9fc5b9d1cccac,
title = "Nuclear demagnetisation cooling of a nanoelectronic device",
abstract = "We present a new technique for on-chip cooling of electrons in a nanostructure: nuclear demagnetisation of on-chip, thin-film copper refrigerant. We are motivated by the potential improvement in the operation of nanoelectronic devices below 10 mK . At these temperatures, weak electron-phonon coupling hinders traditional cooling, yet here gives the advantage of thermal isolation between the environment and the on-chip electrons, enabling cooling significantly below the base temperature of the host lattice. To demonstrate this we electroplate copper onto the metallic islands of a Coulomb blockade thermometer (CBT), and hence provide a direct thermal link between the cooled copper nuclei and the device electrons. The CBT provides primary thermometry of its internal electron temperature, and we use this to monitor the cooling. Using an optimised demagnetisation profile we observe the electrons being cooled from 9 mK to 4 . 5 mK , and remaining below 5 mK for an experimentally useful time of 1200 seconds. We also suggest how this technique can be used to achieve sub- 1 mK electron temperatures without the use of elaborate bulk demagnetisation stages.",
author = "Alex Jones and Ian Bradley and Tony Gu{\'e}nault and David Gunnarsson and Richard Haley and Stephen Holt and Yuri Pashkin and Jari Penttil{\"a} and Jonathan Prance and Mika Prunnila and Leif Roschier",
year = "2017",
language = "English",
journal = "APS March Meeting 2017",

}

RIS

TY - JOUR

T1 - Nuclear demagnetisation cooling of a nanoelectronic device

AU - Jones, Alex

AU - Bradley, Ian

AU - Guénault, Tony

AU - Gunnarsson, David

AU - Haley, Richard

AU - Holt, Stephen

AU - Pashkin, Yuri

AU - Penttilä, Jari

AU - Prance, Jonathan

AU - Prunnila, Mika

AU - Roschier, Leif

PY - 2017

Y1 - 2017

N2 - We present a new technique for on-chip cooling of electrons in a nanostructure: nuclear demagnetisation of on-chip, thin-film copper refrigerant. We are motivated by the potential improvement in the operation of nanoelectronic devices below 10 mK . At these temperatures, weak electron-phonon coupling hinders traditional cooling, yet here gives the advantage of thermal isolation between the environment and the on-chip electrons, enabling cooling significantly below the base temperature of the host lattice. To demonstrate this we electroplate copper onto the metallic islands of a Coulomb blockade thermometer (CBT), and hence provide a direct thermal link between the cooled copper nuclei and the device electrons. The CBT provides primary thermometry of its internal electron temperature, and we use this to monitor the cooling. Using an optimised demagnetisation profile we observe the electrons being cooled from 9 mK to 4 . 5 mK , and remaining below 5 mK for an experimentally useful time of 1200 seconds. We also suggest how this technique can be used to achieve sub- 1 mK electron temperatures without the use of elaborate bulk demagnetisation stages.

AB - We present a new technique for on-chip cooling of electrons in a nanostructure: nuclear demagnetisation of on-chip, thin-film copper refrigerant. We are motivated by the potential improvement in the operation of nanoelectronic devices below 10 mK . At these temperatures, weak electron-phonon coupling hinders traditional cooling, yet here gives the advantage of thermal isolation between the environment and the on-chip electrons, enabling cooling significantly below the base temperature of the host lattice. To demonstrate this we electroplate copper onto the metallic islands of a Coulomb blockade thermometer (CBT), and hence provide a direct thermal link between the cooled copper nuclei and the device electrons. The CBT provides primary thermometry of its internal electron temperature, and we use this to monitor the cooling. Using an optimised demagnetisation profile we observe the electrons being cooled from 9 mK to 4 . 5 mK , and remaining below 5 mK for an experimentally useful time of 1200 seconds. We also suggest how this technique can be used to achieve sub- 1 mK electron temperatures without the use of elaborate bulk demagnetisation stages.

M3 - Meeting abstract

JO - APS March Meeting 2017

JF - APS March Meeting 2017

ER -