Signatures of superconducting triplet pairing in Ni-Ga-bilayer junctions

Andreas Costa, Madison Sutula, Valeria Lauter, Jia Song, Jaroslav Fabian, Jagadeesh S. Moodera

Research output: Contribution to journalArticlepeer-review

6 Scopus citations

Abstract

Ni-Ga bilayers are a versatile platform for exploring the competition between strongly antagonistic ferromagnetic and superconducting phases. We characterize the impact of this competition on the transport properties of highly-ballistic Al/Al2O3(/EuS)/Ni-Ga tunnel junctions from both experimental and theoretical points of view. While the conductance spectra of junctions comprising Ni (3 nm)-Ga (60 nm) bilayers can be well understood within the framework of earlier results, which associate the emerging main conductance maxima with the junction films' superconducting gaps, thinner Ni (1.6 nm)-Ga (30 nm) bilayers entail completely different physics, and give rise to novel large-bias (when compared to the superconducting gap of the thin Al film as a reference) conductance-peak subseries that we term conductance shoulders. These conductance shoulders might attract considerable attention also in similar magnetic superconducting bilayer junctions, as we predict them to offer an experimentally well-accessible transport signature of superconducting triplet pairings that are induced around the interface of the Ni-Ga bilayer. We further substantiate this claim performing complementary polarized neutron reflectometry measurements on the bilayers, from which we deduce (1) a nonuniform magnetization structure in Ga in a several nanometer-thick area around the Ni-Ga boundary and can simultaneously (2) satisfactorily fit the obtained data only considering the paramagnetic Meissner response scenario. While the latter provides independent experimental evidence of induced triplet superconductivity inside the Ni-Ga bilayer, the former might serve as the first experimental hint of its potential microscopic physical origin. Finally, we introduce a simple phenomenological toy model to confirm also from the theoretical standpoint that superconducting triplet pairings around the Ni-Ga interface can indeed lead to the experimentally observed conductance shoulders, which convinces that our claims are robust and physically justified. Arranging our work in a broader context, we expect that Ni-Ga-bilayer junctions could have a strong potential for future superconducting-spintronics applications whenever an efficient engineering of triplet-pairing superconductivity is required.

Original languageEnglish
Article number033046
JournalNew Journal of Physics
Volume24
Issue number3
DOIs
StatePublished - Mar 1 2022

Funding

The experimental work performed in the US was supported by the NSF C-Accel. Track C under Grant No. 2040620, NSF Grant DMR 1700137, ONR Grants N00014-16-1-2657 and N00014-20-1-2306, and John Templeton Foundation Grants 39944 and 60148. The theoretical work at the University of Regensburg (AC and JF) received funding from the Elite Network of Bavaria through the International Doctorate Program Topological Insulators, and Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) through Subproject B07 within the Collaborative Research Center SFB 1277 (Project-ID 314695032) and the Research Grant ‘Spin and magnetic properties of superconducting tunnel junctions’ (Project-ID 454646522). The undergraduate MS was supported by the UROP program funds at Massachusetts Institute of Technology. This research used resources at the Spallation Neutron Source, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory.

FundersFunder number
NSF C-Accel2040620
UROP
National Science FoundationDMR 1700137
Office of Naval ResearchN00014-16-1-2657, N00014-20-1-2306
Directorate for Mathematical and Physical Sciences1700137
John Templeton Foundation60148, 39944
Massachusetts Institute of Technology
Deutsche Forschungsgemeinschaft314695032, 454646522, SFB 1277
Universität Regensburg

    Keywords

    • paramagnetic Meissner response
    • polarized neutron reflectometry
    • superconducting triplet pairing

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