Experimental study of the proximity effect in thin-film heterostructures with varying thickness of the superconducting lead layer

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Resumo

Systematic studies of the proximity effect of superconductor/normal metal, superconductor/antiferromagnet and superconductor/ferromagnet in structures with varying thickness of the superconducting lead layer have been carried out. It has been shown that in these systems the behavior of the superconducting transition temperature Tc with decreasing thickness of the superconducting layer is different. For superconductor/antiferromagnet structures, within the limits of the studied lead layer thicknesses, changes in Tc are insignificant. As the lead layer thickness decreases, the electrical resistance ratio RRR (R300K/R10K) decreases significantly, which may indicate an increase in the contribution of surface defects. The width of superconducting transitions increases with decreasing thickness of the lead layer, which indicates the manifestation of size effects.

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Sobre autores

А. Kаmаshev

Zаvоisky Physiсаl-Teсhniсаl Institute, Federal Research Сenter Kаzаn Sсientifiс Сenter оf the Russian Аcademy of Sciences

Autor responsável pela correspondência
Email: kаmаndi@mаil.ru
Rússia, Kаzаn

A. Validov

Zаvоisky Physiсаl-Teсhniсаl Institute, Federal Research Сenter Kаzаn Sсientifiс Сenter оf the Russian Аcademy of Sciences

Email: kаmаndi@mаil.ru
Rússia, Kаzаn

D. Arbuzov

Zаvоisky Physiсаl-Teсhniсаl Institute, Federal Research Сenter Kаzаn Sсientifiс Сenter оf the Russian Аcademy of Sciences

Email: kаmаndi@mаil.ru
Rússia, Kаzаn

N. Garif’yanov

Zаvоisky Physiсаl-Teсhniсаl Institute, Federal Research Сenter Kаzаn Sсientifiс Сenter оf the Russian Аcademy of Sciences

Email: kаmаndi@mаil.ru
Rússia, Kаzаn

I. Gаrifullin

Zаvоisky Physiсаl-Teсhniсаl Institute, Federal Research Сenter Kаzаn Sсientifiс Сenter оf the Russian Аcademy of Sciences

Email: kаmаndi@mаil.ru
Rússia, Kаzаn

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2. Fig. 1. Structures of the studied samples: series 1 — MgO/Cu(1.5 nm)/Pb(dPb) (a); series 2 — MgO/CoOx(3.5 nm)/Pb(dPb) (b); series 3 — MgO/Cu(1.5 nm)/Fe(5 nm)/Pb(dPb) (c); series 4 — MgO/Pb(dPb) (d).

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3. Fig. 2. Dependences of the transition temperature to the superconducting state on the thickness of the superconducting lead layer Tc(dPb) for all series of samples.

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4. Fig. 3. Dependences of the ratio of electrical resistances on the thickness of the superconducting lead layer RRR(dPb) for all series of samples.

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5. Fig. 4. Dependences of the widths of superconducting transitions on the thickness of the superconducting lead layer δТс(dPb) for all series of samples.

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