Alloying and strain relaxation effects on spin-reorientation transitions in Cox Ni1-x Cu3 Au (100) ultrathin films

W. C. Lin; B. Y. Wang; Y. W. Liao; Ker Jar Song; Minn Tsong Lin

doi:10.1103/PhysRevB.71.184413

Alloying and strain relaxation effects on spin-reorientation transitions in Cox Ni1-x Cu3 Au (100) ultrathin films

W. C. Lin^*, B. Y. Wang, Y. W. Liao, Ker Jar Song, Minn Tsong Lin

^*此作品的通信作者

研究成果: 雜誌貢獻 › 期刊論文 › 同行評審

24 引文斯高帕斯（Scopus）

摘要

The crystalline structure and the magnetic properties of Cox Ni1-x Cu3 Au (100) films were characterized as functions of thickness and alloy composition. No apparent alloy effect on the crystalline structure was observed with x up to 11%. As the film thickness increases above ∼8 monolayers (ML), the films clearly exhibited a progressively more relaxed structure. Due to the strain relaxation, both the first and the second spin-reorientation transitions (SRT) occurred within 20 ML. The thickness region with perpendicular magnetization was strongly reduced by increasing the Co concentration. For x>10%, no SRT was observed. By combining both the alloy effect and the strain relaxation effect, the SRT boundaries in the phase diagram can be described in a phenomenological model on the basis of magnetoelastics.

原文	英語
文章編號	184413
期刊	Physical Review B - Condensed Matter and Materials Physics
卷	71
發行號	18
DOIs	https://doi.org/10.1103/PhysRevB.71.184413
出版狀態	已發佈 - 2005
對外發佈	是

ASJC Scopus subject areas

電子、光磁材料
凝聚態物理學

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10.1103/PhysRevB.71.184413

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abstract = "The crystalline structure and the magnetic properties of Cox Ni1-x Cu3 Au (100) films were characterized as functions of thickness and alloy composition. No apparent alloy effect on the crystalline structure was observed with x up to 11%. As the film thickness increases above ∼8 monolayers (ML), the films clearly exhibited a progressively more relaxed structure. Due to the strain relaxation, both the first and the second spin-reorientation transitions (SRT) occurred within 20 ML. The thickness region with perpendicular magnetization was strongly reduced by increasing the Co concentration. For x>10%, no SRT was observed. By combining both the alloy effect and the strain relaxation effect, the SRT boundaries in the phase diagram can be described in a phenomenological model on the basis of magnetoelastics.",

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AU - Song, Ker Jar

AU - Lin, Minn Tsong

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N2 - The crystalline structure and the magnetic properties of Cox Ni1-x Cu3 Au (100) films were characterized as functions of thickness and alloy composition. No apparent alloy effect on the crystalline structure was observed with x up to 11%. As the film thickness increases above ∼8 monolayers (ML), the films clearly exhibited a progressively more relaxed structure. Due to the strain relaxation, both the first and the second spin-reorientation transitions (SRT) occurred within 20 ML. The thickness region with perpendicular magnetization was strongly reduced by increasing the Co concentration. For x>10%, no SRT was observed. By combining both the alloy effect and the strain relaxation effect, the SRT boundaries in the phase diagram can be described in a phenomenological model on the basis of magnetoelastics.

AB - The crystalline structure and the magnetic properties of Cox Ni1-x Cu3 Au (100) films were characterized as functions of thickness and alloy composition. No apparent alloy effect on the crystalline structure was observed with x up to 11%. As the film thickness increases above ∼8 monolayers (ML), the films clearly exhibited a progressively more relaxed structure. Due to the strain relaxation, both the first and the second spin-reorientation transitions (SRT) occurred within 20 ML. The thickness region with perpendicular magnetization was strongly reduced by increasing the Co concentration. For x>10%, no SRT was observed. By combining both the alloy effect and the strain relaxation effect, the SRT boundaries in the phase diagram can be described in a phenomenological model on the basis of magnetoelastics.

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Alloying and strain relaxation effects on spin-reorientation transitions in Cox Ni1-x Cu3 Au (100) ultrathin films

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