The Growth and Characterisation of Mn2Au Thin Films and Heterostructures
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Trinity College Dublin. School of Physics. Discipline of Physics
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Casey, Daniel, The Growth and Characterisation of Mn2Au Thin Films and Heterostructures, Trinity College Dublin.School of Physics, 2023
Abstract
In this thesis, Mn2Au thin films and heterostructures are grown via molecular beam
epitaxy. Mn2Au thin films are investigated on MgO (001) and Al2O3 (1102) substrates,
and on Pt (111) seed layer grown on an Al2O3 (0001) substrate. The MgO (001) and
Al2O3 (1102) substrate resulted in polycrystalline films, while the Al2O3(0001)/Pt
(111) substrate and seed layer resulted in high crystalline quality Mn2Au (110) films.
The films were characterised in-situ via reflection high energy electron diffraction,
low energy electron diffraction; and ex-situ via θ − 2θ X-ray diffraction, azimuthal X-
ray diffraction, reciprocal space maps, and X-ray reflectometry. The heterostructures
used Al2O3(0001)/Pt (111) seed layers to grow Co (111)/Mn2Au (110) bilayers and
Fe (110)/Mn2Au (110) bilayers which were structurally analysed using reflection high
energy electron diffraction and θ−2θ X-ray diffraction, as-deposited and after annealing
at 350 ◦ C and 500 ◦ C in an 800 mT applied magnetic field. Magnetic characterisation
of the stacks was performed using room temperature vibrating sample magnetometry,
both as-deposited and after the annealing cycles. The heterostructures were found
to demonstrate exchange coupling between the Co (111)/Mn2Au layers as deposited,
and the field cooling was unable to induce room temperature exchange bias in any of
these. Heterostructures of the form Mn2Au (001)/Fe (001) was grown on an Al2O3
(1102)/Ta (001) substrate/seed layer along with one of the form Mn2Au (110)/Fe
(110) grown on an Al2O3 (0001)/Pt (111) seed layer. These heterostructures were
characterised structurally using reflection high energy electron diffraction, θ − 2θ X-ray
diffraction, and azimuthal X-ray diffraction. The scope of the exchange coupling effect
in these heterostructures was comprehensively investigated using room temperature
vibrating sample magnetometry, both in their as-deposited state and after a field
cooling cycle from 350 ◦ C to room temperature in an 800 mT applied magnetic field.
The exchange coupling effect was also investigated using low temperature vibrating
sample magnetometry measurements in the range of 5 K-270 K, after further field
cooling in a 1 T applied field from 300 K-5 K.
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Sponsor: Irish Research Council (IRC)
Sponsor: Western Digital
Publisher: Trinity College Dublin. School of Physics. Discipline of Physics
Type of material: Thesis

