D. Zhang scite author profile

Magnetic nanostructures that are magnetized perpendicular to their surface are central to many developing technologies, including spintronics devices and patterned media, because of the requirement to maintain thermal stability as device dimensions are scaled further into the nanoscale. Multilayer or superlattice materials such as Co(Fe)/Pd are convenient for these applications due to their highly tunable perpendicular anisotropy [1]. In this study, Co(Fe)/Pd multilayers with structure: Ta/Pd/[Co(Fe)/Pd] X n/Pd were deposited by dc-magnetron sputtering on thermally oxidized Si wafers. Samples were thinned to electron transparency in cross-section and plan-view geometry. High-resolution images were recorded with a JEM-4000EX HREM at 400keV and a CM-200 at 200keV to reveal crystal structure. STEM images were recorded by JEM-2010 to characterize the multilayer interfaces. The magnetic domain structure was studied by off-axis electron holography using a CM-200 equipped with electrostatic biprism and Lorentz lens. In addition, perpendicular magnetic domain morphology and surface roughness was characterized by AFM/MFM. Here, we correlate crystal structure and magnetic properties.Observation of the sample with structure: Ta(3nm)/Pd(3nm)/[Co(4nm)/Pd(11.6nm)]×8/Pd(3nm) using cross-section HR-STEM showed that the multilayer structure increasingly became wavy away from the substrate and the interfaces appeared to be less well-defined [ Fig. 1(a)]. Plan-view HREM images showed a fine-grained microstructure [ Fig. 1(b)] consistent with the {111} texture observed in XTEM images. After saturating the magnetization of the multilayers in specific directions, electron holograms were recorded in field-free conditions using the Lorentz lens [2]. Reconstructed phase maps show fringing magnetic field outside a thick part of the sample in cross-section geometry while only noise is visible within the sample [ Fig. 2(a)]: this result confirms magnetic anisotropy perpendicular to the sample surface. Phase maps reconstructed from the plan-view sample also show fringing fields indicating magnetic anisotropy parallel to the surface [ Fig. 2(b)]. Phase maps also indicate that the magnetic induction is weak but MFM could not reveal any clear magnetic signal. However, MFM images from the sample with structure: Ta(3nm)/Pd(3nm)/[CoFe(t)/Pd(2t)]×12/Pd(3nm) revealed clear domain structure [ Fig. 3], which should make It possible to correlate the magnetic properties of the multilayers with their crystal structure and composition. Further results from samples with different growth parameters will be reported [3].References:[1] J. M. Shaw et al, Phys. Rev.

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Magnetic domain structure in nanocrystalline Ni-Zn-Co spinel ferrite thin films using off-axis electron holography

Zhang

Ray

Petuskey

et al. 2014

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Spin-sprayed Ni-Zn-Co ferrite films with high μ r ″ >100 in extremely wide frequency range 100 MHz-1 GHz J. Appl. Phys. 93, 7133 (2003) We report a study of the magnetic domain structure of nanocrystalline thin films of nickel-zinc ferrite. The ferrite films were synthesized using aqueous spin-spray coating at low temperature ($90 C) and showed high complex permeability in the GHz range. Electron microscopy and microanalysis revealed that the films consisted of columnar grains with uniform chemical composition. Off-axis electron holography combined with magnetic force microscopy indicated a multigrain domain structure with in-plane magnetization. The correlation between the magnetic domain morphology and crystal structure is briefly discussed. V C 2014 AIP Publishing LLC.

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Study of Magnetic Domain Structure in Co(Fe)/Pd Multilayers using Off-axis Electron Holography

Magnetic domain structure in nanocrystalline Ni-Zn-Co spinel ferrite thin films using off-axis electron holography

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