Depth-dependent fct to fcc strain relaxation in CoxNi1-x/Cu3Au(1 0 0) alloy films

Bo Yao Wang; Wen Chin Lin; Yu Wen Liao; Ker Jar Song; Minn Tsong Lin

doi:10.1016/j.susc.2006.07.017

Depth-dependent fct to fcc strain relaxation in Co_xNi_1-x/Cu₃Au(1 0 0) alloy films

Bo Yao Wang, Wen Chin Lin, Yu Wen 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

9 引文斯高帕斯（Scopus）

摘要

Co_xNi_1-x/Cu₃Au(1 0 0) with x ≤ 11% was prepared at room temperature to study the strain relaxation and their correlation with the spin-reorientation transition. The vertical interlayer distance relaxed from 1.66 Å (fct) to 1.76 Å (fcc) while the thickness increased from 8 ML to 18 ML. Such rapid strain relaxation with thickness was attributed to the larger lattice mismatch between Co_xNi_1-x and Cu₃Au(1 0 0) (η ∼ -6.5%). The smooth change for crystalline structure was observed during strain relaxation process in which the crystalline structure seems irrespective of the alloy composition. To explain the strain relaxation, a phenomenological model was proposed. We provide a physical picture that the deeper layers may not relax while the surface layer start to relax. This assumption is based on the several experimental studies. Using the strain averaged from all layers of thin film as the volume strain of magneto-elastic anisotropy energy, the interrelation between strain relaxation and spin reorientation transition can be well described in a Néel type magneto-elastic model.

原文	英語
頁（從 - 到）	4517-4526
頁數	10
期刊	Surface Science
卷	600
發行號	19
DOIs	https://doi.org/10.1016/j.susc.2006.07.017
出版狀態	已發佈 - 2006 10月 1
對外發佈	是

ASJC Scopus subject areas

凝聚態物理學
表面和介面
表面、塗料和薄膜
材料化學

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10.1016/j.susc.2006.07.017

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@article{0254ad6e5a9d4bf591c47d167c7ca3be,

title = "Depth-dependent fct to fcc strain relaxation in CoxNi1-x/Cu3Au(1 0 0) alloy films",

abstract = "CoxNi1-x/Cu3Au(1 0 0) with x ≤ 11% was prepared at room temperature to study the strain relaxation and their correlation with the spin-reorientation transition. The vertical interlayer distance relaxed from 1.66 {\AA} (fct) to 1.76 {\AA} (fcc) while the thickness increased from 8 ML to 18 ML. Such rapid strain relaxation with thickness was attributed to the larger lattice mismatch between CoxNi1-x and Cu3Au(1 0 0) (η ∼ -6.5%). The smooth change for crystalline structure was observed during strain relaxation process in which the crystalline structure seems irrespective of the alloy composition. To explain the strain relaxation, a phenomenological model was proposed. We provide a physical picture that the deeper layers may not relax while the surface layer start to relax. This assumption is based on the several experimental studies. Using the strain averaged from all layers of thin film as the volume strain of magneto-elastic anisotropy energy, the interrelation between strain relaxation and spin reorientation transition can be well described in a N{\'e}el type magneto-elastic model.",

keywords = "Alloy, Co, Magnetic ultrathin film, Ni, Spin-reorientation transition, Strain relaxation",

author = "Wang, {Bo Yao} and Lin, {Wen Chin} and Liao, {Yu Wen} and Song, {Ker Jar} and Lin, {Minn Tsong}",

note = "Funding Information: This work was supported by National Science Council under grant no. NSC 94-2112-M-002-009 and NSC 94-2112-M-001-045.",

year = "2006",

month = oct,

day = "1",

doi = "10.1016/j.susc.2006.07.017",

language = "English",

volume = "600",

pages = "4517--4526",

journal = "Surface Science",

issn = "0039-6028",

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TY - JOUR

T1 - Depth-dependent fct to fcc strain relaxation in CoxNi1-x/Cu3Au(1 0 0) alloy films

AU - Wang, Bo Yao

AU - Lin, Wen Chin

AU - Liao, Yu Wen

AU - Song, Ker Jar

AU - Lin, Minn Tsong

N1 - Funding Information: This work was supported by National Science Council under grant no. NSC 94-2112-M-002-009 and NSC 94-2112-M-001-045.

PY - 2006/10/1

Y1 - 2006/10/1

N2 - CoxNi1-x/Cu3Au(1 0 0) with x ≤ 11% was prepared at room temperature to study the strain relaxation and their correlation with the spin-reorientation transition. The vertical interlayer distance relaxed from 1.66 Å (fct) to 1.76 Å (fcc) while the thickness increased from 8 ML to 18 ML. Such rapid strain relaxation with thickness was attributed to the larger lattice mismatch between CoxNi1-x and Cu3Au(1 0 0) (η ∼ -6.5%). The smooth change for crystalline structure was observed during strain relaxation process in which the crystalline structure seems irrespective of the alloy composition. To explain the strain relaxation, a phenomenological model was proposed. We provide a physical picture that the deeper layers may not relax while the surface layer start to relax. This assumption is based on the several experimental studies. Using the strain averaged from all layers of thin film as the volume strain of magneto-elastic anisotropy energy, the interrelation between strain relaxation and spin reorientation transition can be well described in a Néel type magneto-elastic model.

AB - CoxNi1-x/Cu3Au(1 0 0) with x ≤ 11% was prepared at room temperature to study the strain relaxation and their correlation with the spin-reorientation transition. The vertical interlayer distance relaxed from 1.66 Å (fct) to 1.76 Å (fcc) while the thickness increased from 8 ML to 18 ML. Such rapid strain relaxation with thickness was attributed to the larger lattice mismatch between CoxNi1-x and Cu3Au(1 0 0) (η ∼ -6.5%). The smooth change for crystalline structure was observed during strain relaxation process in which the crystalline structure seems irrespective of the alloy composition. To explain the strain relaxation, a phenomenological model was proposed. We provide a physical picture that the deeper layers may not relax while the surface layer start to relax. This assumption is based on the several experimental studies. Using the strain averaged from all layers of thin film as the volume strain of magneto-elastic anisotropy energy, the interrelation between strain relaxation and spin reorientation transition can be well described in a Néel type magneto-elastic model.

KW - Alloy

KW - Co

KW - Magnetic ultrathin film

KW - Ni

KW - Spin-reorientation transition

KW - Strain relaxation

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DO - 10.1016/j.susc.2006.07.017

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SN - 0039-6028

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EP - 4526

JO - Surface Science

JF - Surface Science

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ER -

Depth-dependent fct to fcc strain relaxation in CoxNi1-x/Cu3Au(1 0 0) alloy films

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Depth-dependent fct to fcc strain relaxation in Co_xNi_1-x/Cu₃Au(1 0 0) alloy films