Home > Research > Publications & Outputs > Magnetic-field-induced parity effect in insulat...

Research

Keywords

View graph of relations

Magnetic-field-induced parity effect in insulating Josephson junction chains

Research output: Contribution to Journal/MagazineJournal article

Published

Standard

Magnetic-field-induced parity effect in insulating Josephson junction chains. / Duty, Timothy; Cedergren, Karin; Kafanov, Sergey et al.
In: arxiv.org, 26.08.2018.

Research output: Contribution to Journal/MagazineJournal article

Harvard

Duty, T, Cedergren, K, Kafanov, S, Ackroyd, R & Cole, JH 2018, 'Magnetic-field-induced parity effect in insulating Josephson junction chains', arxiv.org.

APA

Duty, T., Cedergren, K., Kafanov, S., Ackroyd, R., & Cole, J. H. (2018). Magnetic-field-induced parity effect in insulating Josephson junction chains. arxiv.org.

Vancouver

Duty T, Cedergren K, Kafanov S, Ackroyd R, Cole JH. Magnetic-field-induced parity effect in insulating Josephson junction chains. arxiv.org. 2018 Aug 26.

Author

Duty, Timothy ; Cedergren, Karin ; Kafanov, Sergey et al. / Magnetic-field-induced parity effect in insulating Josephson junction chains. In: arxiv.org. 2018.

Bibtex

@article{f1b98cd6c681420fb640e00fec625ad9,
title = "Magnetic-field-induced parity effect in insulating Josephson junction chains",
abstract = "We report the experimental manifestation of even-odd parity effects in the transport characteristics of insulating Josephson junction chains which occur as the superconducting gap is suppressed by applied magnetic fields at millikelvin temperatures. The primary signature is a non-monotonic dependence of the critical voltage, $V_c$, for the onset of charge transport through the chain, with the parity crossover indicated by a maximum of $V_c$ at the parity field $B^*$. We also observe a distinctive change in the transport characteristics across the parity transition, indicative of Cooper-pair dominated transport below $B^*$, giving way to single-electron dominated transport above $B^*$. For fields applied in the plane of the superconducting aluminum films, the parity effect is found to occur at the field, $B^*_{||}$, such that the superconducting gap equals the single-electron charging energy, $\Delta(B^*_{||})=E_C$. On the contrary, the parity effect for perpendicularly applied fields can occur at relatively lower fields, $B^*_\perp\simeq 2\Phi_0/A_I$, depending only on island area, $A_I$. Our results suggest a novel explanation for the insulating peak observed in disordered superconducting films and one-dimensional strips patterned from such films.",
keywords = "cond-mat.mes-hall, cond-mat.supr-con",
author = "Timothy Duty and Karin Cedergren and Sergey Kafanov and Roger Ackroyd and Cole, {Jared H.}",
note = "10 pages including figures and supplemental material",
year = "2018",
month = aug,
day = "26",
language = "English",
journal = "arxiv.org",

}

RIS

TY - JOUR

T1 - Magnetic-field-induced parity effect in insulating Josephson junction chains

AU - Duty, Timothy

AU - Cedergren, Karin

AU - Kafanov, Sergey

AU - Ackroyd, Roger

AU - Cole, Jared H.

N1 - 10 pages including figures and supplemental material

PY - 2018/8/26

Y1 - 2018/8/26

N2 - We report the experimental manifestation of even-odd parity effects in the transport characteristics of insulating Josephson junction chains which occur as the superconducting gap is suppressed by applied magnetic fields at millikelvin temperatures. The primary signature is a non-monotonic dependence of the critical voltage, $V_c$, for the onset of charge transport through the chain, with the parity crossover indicated by a maximum of $V_c$ at the parity field $B^*$. We also observe a distinctive change in the transport characteristics across the parity transition, indicative of Cooper-pair dominated transport below $B^*$, giving way to single-electron dominated transport above $B^*$. For fields applied in the plane of the superconducting aluminum films, the parity effect is found to occur at the field, $B^*_{||}$, such that the superconducting gap equals the single-electron charging energy, $\Delta(B^*_{||})=E_C$. On the contrary, the parity effect for perpendicularly applied fields can occur at relatively lower fields, $B^*_\perp\simeq 2\Phi_0/A_I$, depending only on island area, $A_I$. Our results suggest a novel explanation for the insulating peak observed in disordered superconducting films and one-dimensional strips patterned from such films.

AB - We report the experimental manifestation of even-odd parity effects in the transport characteristics of insulating Josephson junction chains which occur as the superconducting gap is suppressed by applied magnetic fields at millikelvin temperatures. The primary signature is a non-monotonic dependence of the critical voltage, $V_c$, for the onset of charge transport through the chain, with the parity crossover indicated by a maximum of $V_c$ at the parity field $B^*$. We also observe a distinctive change in the transport characteristics across the parity transition, indicative of Cooper-pair dominated transport below $B^*$, giving way to single-electron dominated transport above $B^*$. For fields applied in the plane of the superconducting aluminum films, the parity effect is found to occur at the field, $B^*_{||}$, such that the superconducting gap equals the single-electron charging energy, $\Delta(B^*_{||})=E_C$. On the contrary, the parity effect for perpendicularly applied fields can occur at relatively lower fields, $B^*_\perp\simeq 2\Phi_0/A_I$, depending only on island area, $A_I$. Our results suggest a novel explanation for the insulating peak observed in disordered superconducting films and one-dimensional strips patterned from such films.

KW - cond-mat.mes-hall

KW - cond-mat.supr-con

M3 - Journal article

JO - arxiv.org

JF - arxiv.org

ER -