Critical current of a Josephson junction containing a conical magnet

Gábor B. Halász, J. W.A. Robinson, James F. Annett, M. G. Blamire

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43 Scopus citations

Abstract

We calculate the critical current of a superconductor/ferromagnetic/ superconductor (S/FM/S) Josephson junction in which the FM layer has a weakened conical magnetic structure composed of an in-plane rotating antiferromagnetic phase and an out-of-plane ferromagnetic component. In view of the realistic electronic properties and magnetic structures that can be formed when conical magnets such as Ho are grown with a polycrystalline structure in thin-film form by methods such as direct current sputtering and evaporation, we have modeled this situation in the dirty limit with a large magnetic coherence length (ξf). This means that the electron mean free path is much smaller than the normalized spiral length λ/2π which in turn is much smaller than ξf (with λ as the length a complete spiral makes along the growth direction of the FM). In this physically reasonable limit we have employed the linearized Usadel equations: we find that the triplet correlations are short ranged and manifested in the critical current as a rapid oscillation on the scale of λ/2π. These rapid oscillations in the critical current are superimposed on a slower oscillation which is related to the singlet correlations. Both oscillations decay on the scale of ξf. We derive an analytical solution and also describe a computational method for obtaining the critical current as a function of the conical magnetic layer thickness.

Original languageEnglish
Article number224505
JournalPhysical Review B - Condensed Matter and Materials Physics
Volume79
Issue number22
DOIs
StatePublished - Jun 8 2009
Externally publishedYes

Funding

FundersFunder number
Engineering and Physical Sciences Research CouncilEP/E026206/1, EP/F016646/1, EP/F016611/1

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