芬基超导体/铁磁体双层超导临界温度

IF 0.2 Q4 PHYSICS, APPLIED

Progress in Superconductivity and Cryogenics Pub Date : 2016-06-30 DOI:10.9714/PSAC.2016.18.2.005

T. Hwang, D. Kim

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引用次数: 0

摘要

本文研究了超导体/铁磁双层膜的超导转变温度随铁磁层厚度的变化。FeN用于铁磁性(F)层，NbN和Nb用于超导(S)层。采用三种不同厚度的S层:NbN/FeN (NbN厚度d NbN≈9.3 nm和d NbN≈10 nm)和Nb/FeN (Nb厚度d Nb≈15 nm)。温度随铁磁层厚度d FeN的增加而急剧下降，在d NbN≈10 nm和d Nb≈15 nm时，超导性分别在d FeN≈6.3 nm和d FeN≈2.5 nm处达到最大抑制。在温度达到浅最小值后，在NbN/FeN双层中观察到微弱的温度振荡，而在Nb/FeN双层中几乎观察不到。

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Superconducting critical temperature in FeN-based superconductor/ferromagnet bilayers

We present an experimental investigation of the superconducting transition temperatures, T c , of superconductor/ferromagnet bilayers with varying the thickness of ferromagnetic layer. FeN was used for the ferromagnetic (F) layer, and NbN and Nb were used for the superconducting (S) layer. The results were obtained using three different-thickness series of the S layer of the S/F bilayers: NbN/FeN with NbN thickness, d NbN ≈ 9.3 nm and d NbN ≈ 10 nm, and Nb/FeN with Nb thickness d Nb ≈ 15 nm. T c drops sharply with increasing thickness of the ferromagnetic layer, d FeN , before maximal suppression of superconductivity at d FeN ≈6.3 nm for d NbN ≈10 nm and at d FeN ≈2.5 nm for d Nb ≈ 15 nm, respectively. After shallow minimum of T c , a weak T c oscillation was observed in NbN/FeN bilayers, but it was hardly observable in Nb/FeN bilayers.

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来源期刊

Progress in Superconductivity and Cryogenics PHYSICS, APPLIED-

CiteScore

0.40

自引率

33.30%

发文量

期刊介绍： Progress in Superconductivity and Cryogenics is the official publication of The Korea Institute of Applied Superconductivity and Cryogenics and the Korean Superconductivity Society. It was launched in 1999, and accepts original research articles and review papers on research on superconductivity and related fields of physics, electronic devices, materials science, large-scale applications for magnets, power and energy, and cryogenics. The Journal is published quarterly in March, June, September, and December each year. Supplemental issues are published occasionally. The official title of the journal is ''Progress in Superconductivity and Cryogenics'' and the abbreviated title is ''Prog. Supercond. Cryog.'' All submitted manuscripts are peer-reviewed by two reviewers. The text must be written in English. All the articles in this journal are KCI and SCOPUS as of 2015. The URL address of the journal is http://psac.kisac.org where full text is available. This work was supported by the Korean Federation of Science and Technology Societies grant funded by the Korea government.