Subject View:  - All Sciences - Agricultural and Biological Sciences Arts and Humanities Biochemistry, Genetics, and Molecular Biology Business, Management and Accounting Chemical Engineering Chemistry Civil Engineering Computer Science Decision Sciences Earth and Planetary Sciences Economics, Econometrics and Finance Energy and Power Engineering and Technology Environmental Science Immunology and Microbiology Materials Science Mathematics Medicine Neuroscience Pharmacology, Toxicology and Pharmaceutics Physics and Astronomy Psychology Social Science

Quick Search:  within These Articles in PressThis JournalAll JournalsAll Sources

52 of 633

	This document
		SummaryPlus
		Article
		Journal Format-PDF (103 K)
	Actions
		Cited By
		Save as Citation Alert
		Export Citation

DOI: 10.1016/S0304-8853(01)01357-9
PII: S0304-8853(01)01357-9
Copyright © 2002 Published by Elsevier Science B.V. All rights reserved.

Micromagnetic structures in square magnetic nanodots

M. Maicas^a, M. A. Rivero^a, E. López^{, , a}, M. C. Sánchez^a, C. Aroca^b and P. Sánchez<sup>b

a</sup> Departmento de Física de Materiales, Facultad de CC. Físicas, Univ. Complutense, 28040 Madrid, Spain
^b I.S.O.M., E.T.S.I. Telecomunicación, Univ. Politécnica, 28040 Madrid, Spain

Available online 24 December 2001.

Abstract

The structure of magnetization in magnetic square dots is studied in the range of tens of nanometer by means of micromagnetic simulations. Two magnetic configurations are found, diagonal and vortex structures for thin films, flower and vortex for magnetic nanocubes and a hybrid flower in bulk and vortex near the surfaces for dots with thicknesses larger than dot edge length.

Author Keywords: Micromagnetism; Nanodot; Magnetostatic; Simulation

Article Outline

References

References

1. L. Torres et al.J. Appl. Phys. 85 8 (1999), p. 6208. Abstract-INSPEC |  $Order Document | OJPS full text | Full-text via CrossRef

2. L. Abelmann et al.J. Appl. Phys. 87 9 (2000), p. 5538. Abstract-INSPEC |  $Order Document | OJPS full text | Full-text via CrossRef

3. A.E. LaBonte J. Appl. Phys. 40 (1969), p. 2450. Abstract-INSPEC |  $Order Document

4. M. Mansuripur and R. Giles IEEE Trans. Magn. 24 (1988), p. 2326. Abstract-INSPEC | Abstract-Compendex |  $Order Document

5. R.P. Cowburn J. Phys. D: Appl. Phys. 33 (2000), pp. R1_¯R16. Abstract-Compendex | Abstract |  $Order Document | Full-text via CrossRef

6. J. Miltat et al.Proceedings of the Congress on Trends in nanotechnology, Toledo, Spain (2000).

7. M.A. Rivero et al., Proceedings of the Congress on Trends in nanotechnology. , Toledo, Spain (2000).

8. M.E. Schabes and H.N. Bertram J. Appl. Phys. 64 3 (1988), p. 1347. Abstract-INSPEC |  $Order Document

Corresponding author. Tel.: +34-91-3944549; fax: +34-91-3944547; email: elolopez@eucmax.sim.ucm.es
Note to users: The section "Articles in Press" contains peer reviewed and accepted articles to be published in this journal. When the final article is assigned to an issue of the journal, the "Article in Press" version will be removed from this section and will appear in the associated journal issue. Please be aware that "Articles in Press" do not have all bibliographic details available yet.
There are two types of "Articles in Press":

• Uncorrected proofs: these are articles that are not yet finalized and that will be corrected by the authors. Therefore the text could change before final publication. Uncorrected proofs may be temporarily unavailable for production reasons.
• Corrected proofs: these are articles containing the authors' corrections. The content of the article will remain unchanged, and further corrections are not possible. The only difference with the finally published article is that specific issue and page numbers have not yet been assigned.

	This document SummaryPlus Article Journal Format-PDF (103 K) Actions Cited By Save as Citation Alert Export Citation Journal of Magnetism and Magnetic Materials Article in Press Uncorrected Proof

52 of 633