Electronic structure and magnetism of selected materials

Chiuzbaian, Gheorghe Sorin

30 July 2003

The details of the interplay between the electronic structure and the magnetic properties of matter represent a state of the art challenge. In the present work spectroscopic investigations on the electronic structure of some interesting materials are presented. The achieved information has been used in order to answer specific questions related to the magnetic behavior of the investigated materials. For the transition metal dicyanamide compounds it is shown that the electronic states arising from carbon and nitrogen remain roughly unchanged for all compositions. A model for the magnetic superexchange interaction was proposed. In this model the geometry of the crystallographic structure accounts for a particular interaction pattern while the occupancy of the 3d transition metal band is the factor which triggers the changeover from antiferromagnetic to ferromagnetic interaction. In the case of six-membered ferric-wheel molecules the comparison between experimental and theoretical data issued estimations for the magnitude of magnetic exchange interactions. The information on the electronic structure of the LaNi5-xMex (Me=Cu, Al) allowed a better understanding of their magnetic behavior. The changes induced in the electronic structure of the parent compound by partial substitutions of nickel by copper or aluminum are discussed.

electronic structure

XPS

XES

metal-organic compounds

intermetallic compounds

29 - Physik, Astronomie

75.50.Xx - Molecular magnets

ddc:540

Theoretical investigation of size effects in multiferroic nanoparticles

Allen, Marc Alexander

05 August 2020

Over the last two decades, great progress has been made in the understanding of multiferroic materials, ones where multiple long-range orders simultaneously exist. However, much of the research has focused on bulk systems. If these materials are to be incorporated into devices, they would not be in bulk form, but would be miniaturized, such as in nanoparticle form. Accordingly, a better understanding of multiferroic nanoparticles is necessary. This manuscript examines the multiferroic phase diagram of multiferroic nanoparticles related to system size and surface-induced magnetic anisotropy. There is a particular focus on bismuth ferrite, the room-temperature antiferromagnetic-ferroelectric multiferroic. Theoretical results will be presented which show that at certain sizes, a bistability develops in the cycloidal wavevector. This implies bistability in the ferroelectric and magnetic moments of the nanoparticles. This novel magnetoelectric bistability may be of use in the creation of an electrically-written, magnetically-read memory element. / Graduate

bismuth ferrite

bfo

nanoparticle

nanomagnetism

multiferroics

optimization

magnetism

ferroelectric

bistability

anisotropy

surface anisotropy

weak ferromagnetism

antiferromagnetism

Dzyaloshinskii-Moriya interaction

cycloid

numerical methods

condensed matter

solid state physics

magnetoelectric effect

room-temperature multiferroic

superexchange

magnetic memory

spin canting

g-type antiferromagnetism

Heisenberg Hamiltonian

Nelder-Mead

L-BFGS-B

mathematica

python

ferroelectricity

perovskite

antiferromagnet

bifeo3

rhombohedral

pseudocubic

r3c

trigonal

physics

magnetic

memory

electrically-written memory

curie temperature

néel temperature

materials science