Study of multiferroic materials by means of muon spin rotation and other complementary techniques
Abstract
Magnetic and ferroelectric materials have both had a very important impact in our society,
not only because of the fascinating science behind the two phenomena, but also as a result
of their use in many technological applications. The coupling and coexistence of these
two order parameters within the same material opens the door to exiting new functional
devices. Materials where magnetism and ferroelectricity coexist are known as multiferroic
materials.
In this thesis, muon spectroscopy and other complementary experimental techniques,
including neutron scattering and resonant ultrasound spectroscopy, are used to investigate
two di↵erent multiferroics. Muon and total neutron scattering studies have been
performed on BiFeO3, one of the most studied multiferroic materials. Muon measurements
reveal an anomaly in the temperature region of 200 - 220 K with a sudden and
abrupt change in the muon’s precession frequency that corresponds to a process of muon
di↵usion throughout the entire sample. The pair distribution function, calculated from
total neutron scattering experiments on the compound, suggest that a change in the
local structure of the material involving the bismuth-oxygen bond, in the same temperature
region as the muon di↵usion sets in, is a strong indicative that there is a link
between two in terms of the muon di↵usion being triggered by these local changes. Also,
an extensive analysis and characterisation of the magnetic and ferroelectric properties
of Ba4Dy0.87Nb10O30, an entirely new tetragonal tungsten bronze magnetoelectric material,
is given. Neutron scattering and dielectric measurements are used to show that
this material becomes ferroelectric below 470 K. We use muon spectroscopy and magnetic
susceptibility measurements to investigate the magnetic properties of the material.
Muon measurements under an applied electric field indicate that there is a strong coupling
between the magnetism and ferroelectricity in the material. Resonant ultrasound
spectroscopy is use to investigate whether the source of this coupling could be related
to strain e↵ects. Magnetic neutron scattering measurements show that there is no long
range ordering in the material.
Authors
Aristizabal, CarlosCollections
- Theses [4275]