Tuning the ferromagnetic coupling of Fe nanodots on Cu(111) via dimensionality variation of the mediating electrons

Lifeng Yin; Di Xiao; Zheng Gai; Thomas Z. Ward; Noppi Widjaja; G. Malcolm Stocks; Zhao Hua Cheng; E. Ward Plummer; Zhenyu Zhang; Jian Shen

doi:10.1103/PhysRevLett.104.167202

Tuning the ferromagnetic coupling of Fe nanodots on Cu(111) via dimensionality variation of the mediating electrons

Lifeng Yin
, Di Xiao
, Zheng Gai
, Thomas Z. Ward
, Noppi Widjaja
, G. Malcolm Stocks
, Zhao Hua Cheng
, E. Ward Plummer
, Zhenyu Zhang
, Jian Shen

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Using in situ magneto-optical Kerr effect measurements and phenomenological modeling, we study the tunability in both the magnetization anisotropy and magnetic coupling of Fe nanodots on a curved Cu(111) substrate with varying vicinity. We observe that, as the terrace width w decreases, the magnetization anisotropy increases monotonically, faster when w is smaller than the nanodot size d. In contrast, the magnetic coupling strength also increases until w∼d, after which it decreases steeply. These striking observations can be rationalized by invoking the counterintuitive dimensionality variation of the surface electrons mediating the interdot coupling: the electrons are confined to be one dimensional (1D) when w□d, but become quasi-2D when w<d due to enhanced electron spillover across the steps bridged by the nanodots.

Original language	English
Article number	167202
Journal	Physical Review Letters
Volume	104
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevLett.104.167202
State	Published - Apr 20 2010

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title = "Tuning the ferromagnetic coupling of Fe nanodots on Cu(111) via dimensionality variation of the mediating electrons",

abstract = "Using in situ magneto-optical Kerr effect measurements and phenomenological modeling, we study the tunability in both the magnetization anisotropy and magnetic coupling of Fe nanodots on a curved Cu(111) substrate with varying vicinity. We observe that, as the terrace width w decreases, the magnetization anisotropy increases monotonically, faster when w is smaller than the nanodot size d. In contrast, the magnetic coupling strength also increases until w∼d, after which it decreases steeply. These striking observations can be rationalized by invoking the counterintuitive dimensionality variation of the surface electrons mediating the interdot coupling: the electrons are confined to be one dimensional (1D) when w□d, but become quasi-2D when w",

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T1 - Tuning the ferromagnetic coupling of Fe nanodots on Cu(111) via dimensionality variation of the mediating electrons

AU - Yin, Lifeng

AU - Xiao, Di

AU - Gai, Zheng

AU - Ward, Thomas Z.

AU - Widjaja, Noppi

AU - Stocks, G. Malcolm

AU - Cheng, Zhao Hua

AU - Plummer, E. Ward

AU - Zhang, Zhenyu

AU - Shen, Jian

PY - 2010/4/20

Y1 - 2010/4/20

N2 - Using in situ magneto-optical Kerr effect measurements and phenomenological modeling, we study the tunability in both the magnetization anisotropy and magnetic coupling of Fe nanodots on a curved Cu(111) substrate with varying vicinity. We observe that, as the terrace width w decreases, the magnetization anisotropy increases monotonically, faster when w is smaller than the nanodot size d. In contrast, the magnetic coupling strength also increases until w∼d, after which it decreases steeply. These striking observations can be rationalized by invoking the counterintuitive dimensionality variation of the surface electrons mediating the interdot coupling: the electrons are confined to be one dimensional (1D) when w□d, but become quasi-2D when w

AB - Using in situ magneto-optical Kerr effect measurements and phenomenological modeling, we study the tunability in both the magnetization anisotropy and magnetic coupling of Fe nanodots on a curved Cu(111) substrate with varying vicinity. We observe that, as the terrace width w decreases, the magnetization anisotropy increases monotonically, faster when w is smaller than the nanodot size d. In contrast, the magnetic coupling strength also increases until w∼d, after which it decreases steeply. These striking observations can be rationalized by invoking the counterintuitive dimensionality variation of the surface electrons mediating the interdot coupling: the electrons are confined to be one dimensional (1D) when w□d, but become quasi-2D when w

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DO - 10.1103/PhysRevLett.104.167202

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VL - 104

JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Tuning the ferromagnetic coupling of Fe nanodots on Cu(111) via dimensionality variation of the mediating electrons

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