Current-induced spin-orbit torque effective fields in multilayer structures with perpendicular magnetic anisotropy
Current-induced spin-orbit torque (SOT) effects are usually attributed to spin Hall effect (SHE) occuring in an adjacent nonmagnetic heavy metal layer attached to a ferromagnetic metal (FM) layer and Rashba effect at the FM interface. SOT effects currently draw much attention to the research commu...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2018
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| Online Access: | http://hdl.handle.net/10356/75904 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Current-induced spin-orbit torque (SOT) effects are usually attributed to spin Hall effect (SHE) occuring in an adjacent nonmagnetic heavy
metal layer attached to a ferromagnetic metal (FM) layer and Rashba effect at the FM interface. SOT effects currently draw much attention
to the research community due to their potential of magnetization switching and magnetic domain wall (DW) driving. While being firstly
experimentally observed in the early 2000’s, contradicting results have
been reported about the magnitude of SOT effective fields in nominal
identical systems, the correlation between dampinglike and fieldlike
SOT terms and even unexpected angular dependence behavior of SOT
fields with respect to the magnetization direction have been reported
which requires further understanding of SOT fields in lateral confined
multilayer structures.
In this thesis, various properties of several multilayer structures
with perpendicular magnetic anisotropy (PMA) have been investigated,
notably the influence of magnetization azimuthal variation on SOT
effective fields. First, the quantification of SOT effective fields using
harmonic Hall voltage technique based on anomalous Hall effect (AHE)
only was compared with the in-situ current-induced DW depinning
field method of a pinned DW at the Hall cross. This allows for a direct
comparison of SOT effective fields which manifests the importance
of the planar Hall effect (PHE)-symmetry using the harmonic Hall
voltage technique for SOT effective field investigation. Also, coercivity
and anisotropy fields have been shown to decrease with increasing
current in the magnetic structure which is attributed SOT effects.
With the consideration of the PHE-symmetry in the harmonic Hall
technique method, an analytical solution for a new measurement
approach to quantify SOT effective fields as a function of the magnetization
azimuthal angle has been derived and experimentally successfully
tested in two inherent different sample stacks with PMA. While
usually a negligible azimuthal angular dependence of SOT fields is
expected, an unexpected large angular dependence has been found
for a Pt/(Co/Ni)2/Co/Ta multilayer stack structure. By exploiting
angular symmetries by means of Fourier series expansion of 4
th order which replicates any periodic signal due to its property of the orthogonal
functionality, − sin 2ϕ and − cos 4ϕ dependencies of the SOT fields
with respect to the magnetization azimuthal angle have been found.
A large angular dependent field offset in the first harmonic Hall
voltage has also been observed. Suggesting a unidirectional in-plane
exchange bias (EB)-like field, a formula for the angular dependence of
v the field offset is derived which is well fitted to the data values and confirms
the unidirectional EB field in the Pt/(Co/Ni)2/Co/Ta structure,
which does not exhibit the usually required antiferromagnetic/FM
layers interface. The in-plane EB field is attributed to the composition
of the FM/FM multilayer structure with large/low magnetocrystalline
anisotropy constants in combination with the amorphous Ta capping
layer controlling the grain size of the polycrystalline heterostructure.
The anisotropy field, HK, also exhibits an angular dependence with
spikes at azimuthal angles 45◦ and 225◦. This is mainly attributed to
the reorientation in field offset direction at these angles as well as
intrinsic anisotropy transformations within the structure, as observed
by the change in DW depinning directions and small uncertainties
in the determination of the Hall resistance ratio of PHE/spin Hall
magnetoresistance (SMR) to AHE resistances. The computation of the
anisotropy and SOT fields detection also reveal no influence due to
EB-like field which proposes any correlation of SOT, HK, SMR and EB
must be intrinsically related via spin-orbit coupling (SOC). |
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