Title :
Formation of Magnetic Structure by Domain Wall Confinement in Nanoconstriction
Author :
Duc-The Ngo ; Hickey, M.C. ; McGrouther, D. ; McVitie, S. ; Marrows, C.H. ; Chapman, J.N. ; Awano, Hiromitsu
Author_Institution :
Sch. of Phys. & Astron., Univ. of Glasgow, Glasgow, UK
Abstract :
We present here a study of exploiting Lorentz transmission electron microscopy to observe the magnetic structure in a nanobridge formed by confining a magnetic domain wall. The domain wall is nucleated in an elliptical pad by magnetization reversal and is driven to be pinned at the constriction to form a complex magnetic structure. High-resolution Lorentz microscopy shows that such a structure is composed by a mixture of S and C states of smooth rotation of the magnetization through the nanobridge rather than a conventional single wall as observed previously. This confinement contributes a domain wall resistance observed via anisotropic magnetoresistance presented previously. A serial transformation from S state to S/C mixture, to C state and finally to S state of the topology of the flux is evidently confirmed.
Keywords :
magnetic anisotropy; magnetic domain walls; magnetic structure; magnetisation reversal; magnetoresistance; nanofabrication; nanomagnetics; nanostructured materials; nucleation; transmission electron microscopy; Lorentz transmission electron microscopy; anisotropic magnetoresistance; high-resolution Lorentz microscopy; magnetic domain wall confinement; magnetic structure; magnetization reversal; nanoconstriction; nucleation; smooth rotation; topology; Magnetic domain walls; Magnetic domains; Magnetic resonance imaging; Magnetization; Magnetostatics; Perpendicular magnetic anisotropy; Anisotropic magnetoresistance; Lorentz microscopy; magnetic domain walls; magnetization reversal;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2011.2156395
