Global ETD Search

11	Visualising the charge and Cooper pair density waves in cuprates Edkins, Stephen David January 2016 (has links) The study of cuprate high-temperature superconductors has undergone a recent resurgence due to the discovery of charge order in several families of cuprate materials. While its existence is now well established, little is known about its microscopic origins or its relationship to high-temperature superconductivity and the pseudogap. The aim of the research presented in this thesis is to address these questions. In this thesis I will report on the use of spectroscopic-imaging scanning tunnelling microscopy (SI-STM) to visualise the short-ranged charge density wave (CDW) in Bi₂Sr₂CaCu₂O₈₊ₓ and NaxCa₂₋ₓCuO₂Cl₂. Building on previous measurements of the intra unit-cell electronic structure of cuprates, I introduce sub-lattice segregated SISTM to individually address the atomic sub-lattices in the CuO₂ plane with spatial phase sensitivity. Using this technique I establish that the CDW in Bi₂Sr₂CaCu₂O₈+x and NaxCa₂₋ₓCuO₂Cl₂ has a previously unobserved d-symmetry form factor, where a breaking of rotational symmetry within the unit cell is modulated periodically in space. Towards identifying a mechanism of CDW formation, I establish that the amplitude of CDW modulations in the electronic structure are maximal at the pseudogap energy-scale and that these modulations exhibit a spatial phase difference of π between filled and empty states. Together with the doping evolution of the CDW wave-vector this highlights the role of the low-energy electronic structure of the pseudogap regime in CDW formation. To elucidate the relationship between the CDW and the superconducting condensate I will introduce nanometer resolution scanned Josephson tunnelling microscopy (SJTM). In this approach the Cooper pair (Josephson) tunnelling current between a Bi₂Sr₂CaCu₂O₈₊ₓ sample and a scan-able Bi₂Sr₂CaCu₂O₈₊ₓ nano-flake STM tip is used to directly visualise the superconducting condensate. I will report the observation of a periodic modulation in the Cooper pair condensate at the same wave-vector as the CDW, the first direct detection of a periodically modulating condensate in any superconductor. 537.6
12	Generation of micro/nano metallic nanostructures using self-assembled monolayers as template and electrochemistry She, Zhe January 2012 (has links) This thesis studies a scheme to fabricate small-scaled metal structures by electrochemical metal deposition and lift off. The key point is the use of self-assembled monolayers (SAMs) to control both interfacial charge transfer in electrodeposition and adhesion of the deposit to the substrate. Patterned SAMs exhibiting blocking and non-blocking areas are applied as templates in electrochemical deposition of Cu or Au. Thiol SAMs on Au substrates are used, namely alkane thiols and thiols combining an aliphatic chain with a biphenyl or biphenyl analogous pyridine-phenyl moieties. The patterning of SAMs is realised with microcontact printing (μCP) and electron beam lithography. Electrochemical deposition based on defects in the SAMs is optimised towards generating small nanostructures and depending on the system single or stepped potential procedures are applied. Generated metal structures are transferred to an insulator by lift off. Au microstructures (~10 μm) have been made with microcontact printing and transferred onto epoxy glue, which can potentially be used as microelectrodes in electroanalytical chemistry. Sub-100 nm Cu features and sub-40 nm Au features have been created with electron beam lithography respectively. Lift off process has successfully transferred Cu nanostructures onto epoxy glue with high precision. In contrast to the deposition mediated by defects, Cu deposition mediated by discharging Pd²⁺ coordinated to a pyridine terminated SAM directly through the SAM molecules has been explored as a new approach. This new approach has potential to decrease the size of the metal structure further and the preliminary results show possibility of sub-10 nm features. SAMs prepared with a newly synthesised molecule, 3-(4'-(methylthio)-[1,1'-biphenyl]-4-yl)propane-1-thiol, are characterised by STM, XPS and NEXAFS. The metal structures are investigated by SEM, AFM and STM. 620.5
13	Organic semiconductor characterisation by scanning tunnelling microscopy and optical spectroscopy / Caractérisation de semi-conducteurs organiques par microscopie à effet tunnel et par spectroscopie optique Lelaidier, Tony 18 July 2016 (has links) Les propriétés électroniques et d'autoassemblage de deux composés organiques, le DHTAP et le bis-pyrène, ont été étudiées par microscopie à effet tunnel (STM), sous ultra-vide et à basse température. Les propriétés optiques ont été étudiées par spectroscopie en cavité résonnante (CRD), également sous ultravide.La croissance du DHTAP a été étudiée sur différents métaux nobles. La croissance du bis-pyrène a été étudiée sur Au(111). Dans chaque cas, les conditions de température idéales pour la formation d’une première couche organisée ont été déterminées. Différents modèles sont proposés pour les structures observées en première couche. La formation de la seconde couche moléculaire à également été étudiée.L'évolution des propriétés optiques, étudié par CRD, du bis-pyrène déposé sur du verre borosilicate combinée aux informations obtenues par STM ont permit d’associer ces modifications aux interactions des moments dipolaires de transition des molécules de la première et de la seconde couche et on également permit de déterminer le mode de croissance.Finalement, la possibilité d’induire des modifications chimique de la molécule de DHTAP, intégrée dans une couche auto-assemblée, en utilisant le courant tunnel du STM a été observé. Il s’avère que la molécule de DHTAP intégrée en première couche peut subir une double déshydrogénation pour conduire à la formation d’un composé identifié comme étant le 5,7,12,14-tetraazapentacene (TAP). En seconde couche, la formation de deux radicaux, en plus du TAP, a été observé. La molécule de TAP présente un certain intérêt du fait qu’elle n’est pas synthétisable pas les méthodes conventionnelle de chimie organique. / Electronic and self-assembling properties of two organic compound, the DHTAP and the bis-pyrene, have been studied by the means of low temperature scanning tunnelling microscopy (STM) under ultrahigh vacuum conditions. Optical properties have been studied by cavity ring-down (CRD) spectroscopy, also under ultrahigh vacuum conditions.The growth of DHTAP has been studied on different metallic substrate. The growth of bis-pyrene has been studied on Au(111). In each case, the optimal temperature conditions for the formation of a well-ordered first monolayer have been determined. The formation of second monolayers has also been studied. The evolution of the optical properties, studied by CRD, of bis-pyrene deposited on borosilicate glass combined with information obtained from STM allow us to identify these modifications as interactions between transition dipole moments of molecules in the first and in the second layer, and also determine the growth mode.Finally, the possibility to induce chemical modification of DHTAP molecules embedded in an ordered monolayer using the tunnelling current of the STM has been studied. It appears that the molecule embedded in the first ML can be doubly dehydrogenated which leads to the formation of a compound identified as 5,7,12,14-tetraazapentacene (TAP). In the second layer, the formation of two radicals in addition to the TAP has been observed. The TAP molecule is interesting because of that it cannot be synthesized using common organic chemical methods. Semiconducteur organique Auto-Assemblage Microscope à effet tunnel Spectroscopie en cavité résonnante Ultra-Vide. Organic semiconductor Self-Assembly Scanning tunnelling microscopy Cavity ring down spectroscopy Ultra-High vacuum 620
14	The self-assembly of nucleic acid bases on metal and mineral surfaces Shvarova, Olga Y. January 2011 (has links) The ability of RNA bases to self-assemble into larger structures is an important research area relevant to the origins of life. In the RNA helix the bases are arranged on a sugar-phosphate carcass but it has been suggested that the initial ordering could form on a flat surface. This thesis is an attempt to establish experimentally whether the complementary RNA bases, adenine and uracil, have the ability to self-assemble into large ordered structures when adsorbed on metal and mineral surfaces. The Au (111) surface was chosen as a preferred substrate as it is flat, relatively free of defects, chemically inert and reconstructs in a characteristic pattern of corrugation lines, which provide a reference for crystallographic directions. Six of the molecular phases shown were observed for the first time with molecular resolution and the possible two-dimensional arrangements of adenine and uracil molecules for these phases are proposed. The pure adenine and pure uracil structures have chiral unit cells and in the case of pure uracil alternating monochiral domains within the polychiral islands are created. Well-ordered intricate uracil-adenine bimolecular networks were also observed. The self-assembly of both uracil and adenine appears to be weakly influenced by the surface crystallography. The (100) surface of the mineral pyrite (FeS₂) was chosen as the alternative substrate as it is the most common face that occurs naturally in pyrite crystals. The experiments show the formation of small adenine and uracil crystals at the terrace edges. Neither uracil nor adenine were observed to form a monolayer on the surface of the terraces. The results of the experiments described in this thesis are very interesting in terms of establishing the possible mechanisms for creating regular chiral molecular networks and provide a useful insight into the role of surfaces in the processes of self-assembly of RNA bases. 530.417
15	Probing the effect of oxygen vacancies in strontium titanate single crystals Rahman, Shams ur January 2014 (has links) This thesis describes investigations into the role of non-stoichiometry in the surface and bulk properties of SrTiO<sub>3</sub> single crystals. A family of (n×n) reconstructions, where n = 2, 3, 4, 5, 6 are produced by argon ion sputtering of the SrTiO<sub>3</sub> (111) single crystals and subsequent annealing in UHV or in an oxygen rich environment. The sputtering process introduces defects or oxygen vacancies in the surface region of the sample, whilst the annealing gives rise to surface reconstructions. The surface preparation conditions such as sputtering time, annealing temperature and environment are optimized to obtain various reconstructions in a controlled and reproducible manner. High resolution STM images of these reconstructions are also obtained and utilized in the investigation of the surface reactivity. Fullerene molecules are deposited on the reconstructed surfaces to elucidate the surface reactivity through template assisted growth. Fullerene molecules are first deposited with substrate surfaces held at room temperature. Being the most highly reduced among the (n×n) family, the 5×5 reconstruction significantly influenced the growth of fullerenes. Both C<sub>60</sub> and C<sub>70</sub> adsorb as individual molecules and produce clusters with magic numbers. The 4×4 and 6×6 reconstructed surfaces encourage the formation of close-packed structures upon the deposition at room temperature. When the surface covered with fullerenes is heated to a temperature of around 200 °C, epitaxial islands are observed. The 6×6 reconstructed surface appeared to be less reactive than the 4×4. Electrical transport, cathodoluminescence (CL) and electron spin resonance (ESR) experiments are also carried out to investigate the effect of oxygen vacancies on the bulk properties of UHV annealed SrTiO<sub>3</sub> single crystals. Thermal reduction leads to carrier doping of the material, which not only gives rise to electrical conduction but also induces room temperature luminescence. Both the electrical conductivity and CL intensity increases with annealing time. The work presented in this thesis provides insight into the defect driven properties in both the surface and bulk of SrTiO<sub>3</sub> single crystals, which could play an important role in the development of oxide-based electronic devices. 620.1
16	Etude de l'interface graphène - SiC(000-1) (face carbone) par microscopie à effet tunnel et simulations numériques ab initio / Investigation of the graphene - SiC(000-1) (carbon face) interface using scanning tunneling microscopy and ab initio numerical simulations Hiebel, Fanny 13 December 2011 (has links) Le graphène est un cristal bidimensionnel composé d'atomes de carbone arrangés sur un réseau en nids d'abeille. Ce matériau présente des propriétés électroniques intéressantes tant au niveau fondamental qu'en vue d'applications avec notamment une structure de bande exotique en « cône de Dirac » et de grandes mobilités de porteurs. Sa fabrication par graphitisation du SiC est particulièrement adaptée aux applications électroniques. Nous avons étudié ce système par microscopie à effet tunnel (STM) et simulations numériques ab initio avec comme objectif la caractérisation au niveau atomique de l'interface graphène - SiC(000-1) (face carbone) et l'étude de l'impact du substrat sur la structure électronique du graphène. Après un chapitre introductif à la thématique du graphène, suivi d'un chapitre présentant les deux techniques utilisées au cours de ce travail, nous présentons nos échantillons faiblement graphitisés obtenus sous ultra-vide. Nous avons identifié deux types d'interfaces, les reconstructions natives de la surface du SiC(000-1) appelées (2x2)C et (3x3), sur lesquelles reposent les ilots monoplan de graphène, avec un fort désordre rotationnel donnant lieu à des figures de moiré sur les images STM. Nous montrons par imagerie STM et spectroscopie tunnel que l'interaction graphène/(3x3) est très faible. Nous étudions ensuite le cas d'interaction plus forte graphène/(2x2) successivement du point de vue des états du graphène et des états de la reconstruction, dans l'espace direct et réciproque, de façon expérimentale et théorique. Enfin, nous considérons l'effet de défauts observés par STM à l'interface des ilots sur (2x2), modélisés par des adatomes d'hydrogène, sur le dopage et la structure de bande électronique du graphène. / Graphene refers to a two-dimensional crystal made of carbon atoms arranged on a honeycomb lattice. This material presents interesting electronic properties regarding fundamental physics as well as industrial applications, such as an exotic low-energy band structure and high charge carrier mobility. Its fabrication through the graphitization of SiC is a promising method for electronics. We studied this system using scanning tunnelling microscopy (STM) and ab initio numerical simulations with the aim of characterizing the graphene - SiC(000-1) (carbon face) interface and studying the impact of the substrate on graphene's electronic structure. After an introduction to the graphene topic and a description of our investigation techniques, we present our lightly graphitized samples obtained under ultra-high vacuum. We identify two interface structures, the native SiC(000-1) surface reconstructions named (2x2)C and (3x3), on top of which lie graphene monolayer islands with a high rotational disorder leading to various moiré patterns on STM images. Using STM, we show that the graphene/(3x3) interaction is very weak. We then study the stronger graphene/(2x2) interaction successively from the point of view of the graphene and the reconstruction states, in the direct and reciprocal space, using both our experimental and theoretical methods. Finally, we consider the impact of interfacial defects observed by STM through graphene/(2x2) islands and modelled with hydrogen adatoms on the electronic band structure and doping of graphene Graphène Calculs ab initio Microscopie à effet tunnel Carbure de silicium Physique des surfaces Structure de bande interface défauts Graphene Ab initio calculations Scanning tunnelling microscopy Silicon carbide Surface physics Band structure Interface Defects
17	Odd-frequency pairs and Josephson current through a strong ferromagnet Asano, Yasuhiro, Sawa, Yuki, Tanaka, Yukio, Golubov, Alexander A. 12 1900 (has links) No description available. Cooper pairs electronic density of states exchange interactions (electron) ferromagnetic materials Green's function methods interface states Josephson effect magnetic superconductors mesoscopic systems quasiparticles scanning tunnelling microscopy spin fluctuations triplet state
18	Neuartige Triazol-basierte aromatische Rückgrate für die Makromolekulare und Supramolekulare Chemie Meudtner, Robert M. 05 January 2010 (has links) Ein Ansatz der Darstellung von neuartigen funktionalen Materialien basiert auf der Synthese von Foldameren mit charakteristischen Eigenschaften, die eine Kontrolle über Formgebung und Gestaltung der Makromoleküle und derer Aggregate zulassen. Bislang sind gerade größere Foldamerstrukturen definierter Größe und Form meist schwer darstellbar und eine strukturelle Modifizierbarkeit nicht ohne weiteres möglich. In dieser Arbeit konnte gezeigt werden, dass die hohe Effizienz der seit 2002 bekannten Kupfer(I)-katalysierten 1,3-dipolaren Azid-Alkin-Cycloaddition, kurz “Klick“-Reaktion genannt, verwendet werden kann, um neuartige heteroaromatische Gerüste für die Konstruktion von diversen (makromolekularen) Strukturen zu generieren. Hierbei wird der bei der Reaktion entstehende Triazol-Ring gezielt als funktionale und strukturgebende Einheit genutzt. Zunächst wurden auf einfache und hochmodulare Weise 2,6-Bis(1-aryl-1,2,3-triazol-4-yl)pyridine (BTPs) dargestellt, die in einer hufeisenförmigen, planaren Konformation vorliegen und sich daher als helikogene Einheiten für die Konstruktion von helikalen aromatischen Foldameren eignen. Zudem stellen die BTP-Strukturen eine neue Klasse von pyridinzentrierten, tridentaten Liganden dar. Sie koordinieren an eine Vielzahl von Übergangsmetallionen unter Ausbildung von Metallkomplexen, die über interessante magnetische und lumineszierende Eigenschaften verfügen. Durch die Koordination, aber auch bei Protonierung, lassen sich die BTP-Gerüste von der gebeugten anti-anti-Konformation in eine gestreckte syn-syn-Konformation schalten. Dies wurde in Lösung, im kristallinen Festkörper und an der Flüssig-Fest-Grenzfläche zu Graphit untersucht. Über Selbstorganisation großflächig ausgebildete hochgeordnete BTP-Monoschichten an der Graphitoberfläche lassen sich mit Hilfe der Rastertunnel-Mikroskopie visualisieren und durch oben genannte externe Stimuli umstrukturieren. Eine neue Klasse von (BTP-basierten) responsiven heteroaromatischen oligomeren und polymeren Foldameren wurde mit Hilfe der „Klick“-Reaktion generiert. Die Oligomeren, sogenannte ”Klickamere“, mit einer Länge von 17 aromatischen Ringen zeigen in polaren Lösungsmitteln ein ausgeprägtes helikales Faltungsverhalten. Ein aus 17 aromatischen Ringen bestehender Foldamerstrang ist gegenüber Chloridionen responsiv, wobei es durch die Wechselwirkung mit diesem achiralen Stimulus bemerkenswerter Weise zu einer Helixinversion kommt. Die entsprechenden responsiven Polymere falten in eine stabile helikale Konformation, die bei Zugabe von Metallionen aufbricht und zu der Bildung von koordinativ kreuzverlinkten, stark viskosen Gelen führt. / One approach to develop novel functional materials is based on the synthesis of macromolecules with characteristic properties, in particular foldamers. However, preparation and structural variation of macromolecules of controllable size and specific shape are often cumbersome and versatile synthetic routes are still needed. In this dissertation, the high efficiency of the so called “click”-reaction, i.e. the Cu(I)-catalyzed Huisgen-type 1,3-dipolar cycloaddition, has been used to design a novel class of heteroaromatic (macromolecular) scaffolds. In these structures the formed triazole moieties constitute an essential integral part rather than a mere connecting unit. In a first step, structurally varying 2,6-Bis(1-aryl-1,2,3-triazolyl-4-yl)pyridines (BTPs) have been generated in an easy and modular way. The BTP scaffold adopts a kinked conformation and therefore functions as helicogenic building block for the construction of helical foldamers. Additionally, the BTP framework is responsive towards protonation and transition metal ion complexation, thereby undergoing a significant structural change from the kinked anti-anti into the extended syn-syn conformation. The conformational switching has been investigated in solution and in the solid state but can also be visualized at the liquid-solid interface on graphite by STM imaging. The BTPs represent a novel class of pyridine-centered, tridentate ligands, which form complexes with interesting magnetic and luminescent properties by the coordination to numerous transition metal ions. Varying heteroaromatic oligomeric and polymeric foldamers with remarkable properties have been generated using the “click”-reaction as synthesis tool. The BTP building blocks, which have (partly) been integrated into the backbones, support the stability of the helical conformation and provide responsiveness towards external stimuli. Three oligomer series of different length have been synthesized and analyzed. Oligomers consisting of 17 aromatic rings, termed clickamers, fold into a helical conformation in polar solvents. One of the three clickamers shows an unexpected phenomenon of helix inversion upon interaction with chloride ions as an achiral stimulus. The corresponding polymeric strands fold into an even more stable helical conformation, which breaks up upon exposure to transition metal ions leading to coordinatively crosslinked, highly viscous gels. Selbstorganisation Klick-Chemie Cycloaddition responsive Foldamere Helixinversion Klickamere helikale Polymere Supramolekulare Chemie Rastertunnel-Mikroskopie Präorganisation BTP-Ligand self-assembly click chemistry cycloaddition responsive foldamers helix inversion clickamers helical polymers supramolecular chemistry scanning tunnelling microscopy preorganization BTP ligand 540 Chemie 30 Chemie ddc:540
19	Strukturelle und elektronische Eigenschaften von Nanographen-Graphen-Systemen sowie Schnitt- und Faltverhalten von Graphen Eilers, Stefan 11 April 2013 (has links) Im ersten Teil der Arbeit werden Graphen sowie von Monolagen von auf Nanometer großen Graphenen basierenden Hexa-peri(Dodekyl)-Hexabenzocoronen-Molekülen (HBC-C12), adsorbiert auf Graphen, mit Rastertunnelmikroskopie und –spektroskopie an der Fest-Flüssig-Grenzfläche untersucht. Nanographen-Moleküle selbstaggregieren epitaktisch zu hochgeordneten Monolagen. Die Einheitszellen der Moleküllagen auf Monolage Graphen, Bilage Graphen und auf Graphit sind ununterscheidbar. Die Strukturen der Moleküllagen auf gewellten und flachen Teilen des Graphens stimmen überein. Strom-Spannungs-Kennlinien an Nanographen auf Graphen und auf Graphit weisen auf sehr ähnliche elektronische Eigenschaften hin. Zusammengefasst sind strukturelle sowie elektronische Eigenschaften der Nanographenlage homogen, stabil und definiert. Graphen erweist sich als bestens als Substrat und gleichzeitig als Elektrode für hochgeordnete Lagen von Nanographen-Molekülen geeignet. Im zweiten Teil der Arbeit wird Graphen mit der Sonde eines Rasterkraftmikroskops im Kontaktmodus mechanisch manipuliert. Es wird gezeigt, dass Graphen in nur einem Manipulationsschritt zu Streifen und Spalt geschnitten werden kann. Dieses Verhalten wird mit einem klassischen Modell des Biegens theoretisch erklärt. Das Schnittverhalten liegt in der 2-Dimensionalität des Graphens sowie in dessen Faltbarkeit auf Grund hinreichender Elastizität begründet. Durch mechanische Manipulation mit der Sonde des Rasterkraftmikroskops im Kontaktmodus unter atmosphärischen Bedingungen wird eine Flüssigkeitsschicht zwischen Graphen und dem Siliziumdioxidsubstrat nachgewiesen, welche eine mögliche Erklärung des stark kraftabhängigen Materialkontrasts zwischen Graphen und Siliziumdioxid im Amplitudenmodulationsmodus des Rasterkraftmikroskops darstellt. Weiter wird gezeigt, dass das Falten des Graphens durch mechanische Manipulation eine geeignete Methode zur Herstellung nicht epitaktisch aufeinander gestapelter Graphene darstellt. / In the first part of the thesis graphene as well as monolayers of hexa-peri(dodecyl)-hexabenzocoronene molecules (HBC-C12) based on nanometer sized graphenes adsorbed on graphene is investigated by scanning tunnelling microscopy and tunneling spectroscopy at the solid-liquid interface. The nanographene molecules self-assemble on graphene epitaxially to form highly ordered monolayers. The unit cells of the molecular layers on monolayer graphene, bilayer graphene and on graphite appear identical. The structures of the molecular layers occur equal on corrugated and on flat parts of graphene. Current-voltage-characteristics show that the electronic properties of nanographene on graphene and on graphite are very similar. Summarized, structural as well as electronic properties of the nanographene layer are homogeneous, stable and defined. Graphene proves to be excellently qualified for simultaneously being substrate as well as electrode for highly ordered layers of nanographene based molecules. In the second part of the thesis graphene is mechanically manipulated in air in contact mode of a scanning force microscope. It is shown that a single manipulation process can lead to a stripe cut out of graphene. This behaviour is theoretically explained by a classical bending model. The cutting behavior originates from the 2-dimensionality of graphene and its folding ability because of sufficient elasticity. A liquid layer between graphene and the silicon dioxide substrate is verified by mechanical manipulation in contact mode of a scanning force microscope. Hence a possible explanation could be found for the strongly force dependent material contrast between graphene and silicon dioxide in amplitude modulation mode of the scanning force microscope. Further, it is demonstrated that folding graphene by mechanical manipulation is a proper method for the production of graphene stacked on each other non-epitaxially. Graphen Rasterkraftmikroskopie Selbstaggregation HBC Flüssigkristall Monolage Nanographen Makromolekül Hexabenzocoronen Rastertunnelmikroskopie RTM Kennlinie Ramanspektroskopie self-assembly manipulation atomic force microscopy scanning tunnelling microscopy AFM STM graphene monolayer liquid crystal nanographene macromolecule hexabenzocoronene SFM STS I-V-characteristics tunneling spectroscopy raman spectroscopy 530 Physik 29 Physik, Astronomie UQ 8225 ddc:530
20	Atomistic simulations of competing influences on electron transport across metal nanocontacts Dednam, Wynand 14 June 2019 (has links) In our pursuit of ever smaller transistors, with greater computational throughput, many questions arise about how material properties change with size, and how these properties may be modelled more accurately. Metallic nanocontacts, especially those for which magnetic properties are important, are of great interest due to their potential spintronic applications. Yet, serious challenges remain from the standpoint of theoretical and computational modelling, particularly with respect to the coupling of the spin and lattice degrees of freedom in ferromagnetic nanocontacts in emerging spintronic technologies. In this thesis, an extended method is developed, and applied for the first time, to model the interplay between magnetism and atomic structure in transition metal nanocontacts. The dynamic evolution of the model contacts emulates the experimental approaches used in scanning tunnelling microscopy and mechanically controllable break junctions, and is realised in this work by classical molecular dynamics and, for the first time, spin-lattice dynamics. The electronic structure of the model contacts is calculated via plane-wave and local-atomic orbital density functional theory, at the scalar- and vector-relativistic level of sophistication. The effects of scalar-relativistic and/or spin-orbit coupling on a number of emergent properties exhibited by transition metal nanocontacts, in experimental measurements of conductance, are elucidated by non-equilibrium Green’s Function quantum transport calculations. The impact of relativistic effects during contact formation in non-magnetic gold is quantified, and it is found that scalar-relativistic effects enhance the force of attraction between gold atoms much more than between between atoms which do not have significant relativistic effects, such as silver atoms. The role of non-collinear magnetism in the electronic transport of iron and nickel nanocontacts is clarified, and it is found that the most-likely conductance values reported for these metals, at first- and lastcontact, are determined by geometrical factors, such as the degree of covalent bonding in iron, and the preference of a certain crystallographic orientation in nickel. / Physics / Ph. D. (Physics) Simulations of nanocontacts Scanning tunnelling microscopy Mechanically controllable break junction Transition metals Ferromagnetism Magnetoresistance Noncollinear spins Domain walls Density functional theory Scalar relativistic Spin-orbit coupling Classical molecular dynamics Spin-lattice dynamics Magnetocrystalline anisotropy Quantum transport calculations Non-equilibrium Green’s Functions 538.4 Electron transport Scanning tunneling microscopy Transition metals Ferromagnetism Magnetoresistance Density functionals

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