Self-Assembly of Nanometer-Scale Magnetic Dots with Narrow Size Distributions on an Insulating Substrate

Zheng Gai; Biao Wu; J. P. Pierce; G. A. Farnan; Dajun Shu; Mu Wang; Zhenyu Zhang; Jian Shen

doi:10.1103/PhysRevLett.89.235502

Self-Assembly of Nanometer-Scale Magnetic Dots with Narrow Size Distributions on an Insulating Substrate

Zheng Gai, Biao Wu, J. P. Pierce, G. A. Farnan, Dajun Shu, Mu Wang, Zhenyu Zhang, Jian Shen

Scanning Tunneling Microscopy Group

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

66 Scopus citations

Abstract

The self-assembly of iron dots on the insulating surface of NaCl(001) is investigated experimentally and theoretically. Under proper growth conditions, nanometer-scale magnetic iron dots with remarkably narrow size distributions can be achieved in the absence of a wetting layer. Furthermore, both the vertical and lateral sizes of the dots can be tuned with the iron dosage without introducing apparent size broadening, even though the clustering is clearly in the strong coarsening regime. These observations are interpreted using a phenomenological mean-field theory, in which a coverage-dependent optimal dot size is selected by strain-mediated dot-dot interactions.

Original language	English
Journal	Physical Review Letters
Volume	89
Issue number	23
DOIs	https://doi.org/10.1103/PhysRevLett.89.235502
State	Published - 2002

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10.1103/PhysRevLett.89.235502

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title = "Self-Assembly of Nanometer-Scale Magnetic Dots with Narrow Size Distributions on an Insulating Substrate",

abstract = "The self-assembly of iron dots on the insulating surface of NaCl(001) is investigated experimentally and theoretically. Under proper growth conditions, nanometer-scale magnetic iron dots with remarkably narrow size distributions can be achieved in the absence of a wetting layer. Furthermore, both the vertical and lateral sizes of the dots can be tuned with the iron dosage without introducing apparent size broadening, even though the clustering is clearly in the strong coarsening regime. These observations are interpreted using a phenomenological mean-field theory, in which a coverage-dependent optimal dot size is selected by strain-mediated dot-dot interactions.",

author = "Zheng Gai and Biao Wu and Pierce, {J. P.} and Farnan, {G. A.} and Dajun Shu and Mu Wang and Zhenyu Zhang and Jian Shen",

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T1 - Self-Assembly of Nanometer-Scale Magnetic Dots with Narrow Size Distributions on an Insulating Substrate

AU - Gai, Zheng

AU - Wu, Biao

AU - Pierce, J. P.

AU - Farnan, G. A.

AU - Shu, Dajun

AU - Wang, Mu

AU - Zhang, Zhenyu

AU - Shen, Jian

PY - 2002

Y1 - 2002

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AB - The self-assembly of iron dots on the insulating surface of NaCl(001) is investigated experimentally and theoretically. Under proper growth conditions, nanometer-scale magnetic iron dots with remarkably narrow size distributions can be achieved in the absence of a wetting layer. Furthermore, both the vertical and lateral sizes of the dots can be tuned with the iron dosage without introducing apparent size broadening, even though the clustering is clearly in the strong coarsening regime. These observations are interpreted using a phenomenological mean-field theory, in which a coverage-dependent optimal dot size is selected by strain-mediated dot-dot interactions.

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VL - 89

JO - Physical Review Letters

JF - Physical Review Letters

IS - 23

ER -

Self-Assembly of Nanometer-Scale Magnetic Dots with Narrow Size Distributions on an Insulating Substrate

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