RT Journal Article
T1 Tailoring magnetic anisotropy at will in 3d interconnected nanowire networks
A1 Ruiz Clavijo, Alejandra
A1 Ruiz Gómez, Sandra
A1 Caballero Calero, Olga
A1 Pérez García, Lucas
A1 Martín González, Marisol
AB The control of magnetic anisotropy has been the driving force for the development of magnetic applications in a wide range of technological fields from sensing to spintronics. In recent years, the possibility of tailoring the magnetic properties goes together with a need for new 3D materials to expand the applications to a new generation of devices. Herein, the possibility of designing the magnetic anisotropy of 3D magnetic nanowire networks is shown just by modifying the geometry of the structure or by composition. It is also shown that this is possible when the magnetic properties of the structure are governed by magnetostatic anisotropy. The present approach can guide systematic tuning of the magnetic easy axis and coercivity in the desired direction at the nanoscale. Importantly, this can be achieved on virtually any magnetic material, alloy, or multilayers that can be prepared inside porous alumina. These results are promising for engineering novel magnetic devices that exploit tailored magnetic anisotropy using metamaterials concept.
PB Wiley-V C H VERLAG GMBH
SN 1862-6254
YR 2019
FD 2019-07-19
LK https://hdl.handle.net/20.500.14352/13656
UL https://hdl.handle.net/20.500.14352/13656
LA eng
NO ©2019 Wiley-V C H VERLAG GMBHThe authors acknowledge financial support from INFANTE 201550E072, MAT2017-86450-C4-3-R, and MAT2017-87072-C4-2-P. The authors also acknowledge the service from the X-SEM Laboratory at IMM, and funding from MINECO under project CSIC13-4E-1794 with support from EU (FEDER, FSE) and project MAT2017-87072-C4-2-P. The authors would also like to acknowledge the help of Mr. Pedro Campos with the sketches in the figures along the article.
NO Ministerio de Economía y Competitividad (MINECO)/FEDER
NO Consejo Superior de Investigaciones Científicas (CSIC)
DS Docta Complutense
RD 20 abr 2025