The relations between thermodynamics, nanostructure, hardening and stability of an Al-Cu-Mg alloy processed by high pressure torsion

Chen, Ying

January 2014

This thesis presents a study on microstructural evolutions of an ultrafine-grained (UFG) Al-Cu-Mg alloy processed by high-pressure torsion (HPT). This work aims to develop a physically based hardening model to predict the strength of cluster strengthened UFG ternary alloys, and to reveal the relation between thermodynamics and high strain in severe plastic deformation (SPD). Experiments by means of Vickers hardness, differential scanning calorimetry (DSC), Xray diffraction (XRD), transmission electron microscopy (TEM) and atom probe microscopy (APM) have been carried out to provide the relevant information for the calibration and validation of the models. Analysis of XRD line profile broadening using the Rietveld method and Williamson-Hall method shows that the dislocation density increases significantly due to severe plastic deformation, which contributes to the increase of strength. APM reveals the presence of nanoscale co-clusters and defectsolute clustering. The relation between peak temperature for S phase formation and the equivalent strain for HPT was studied with the aid of a diffusion model. The model suggests that on increasing strain, the exothermic peaks correlated to S precipitation shift to lower temperatures. The model is consistent with the data from DSC thermographs of samples after different number of HPT rotations. In both the strengthening model and the stored energy model, strengthening due to dislocations, grain refinement, co clusters (due to short range order and modulus strengthening) and solute segregation are all incorporated to explain the multiple mechanisms. The models show good correspondences with measured microstructure data, measured hardness and measured enthalpy in DSC. The thermal stability of nanostructures in the Al-Cu-Mg alloy obtained by HPT has been studied during DSC heating processes. A significant increase of crystallite size and a significant decrease of dislocation density are revealed from XRD profile broadening when heat treated up to 210 °C, which correlates with an exothermic peak in DSC thermographs. Clusters are thought to act as obstacles that hinder the movement of dislocations, stabilize the ultrafine microstructures. In single reversal (SR) HPT, the hardness slightly decreases after 1/4 reversal turn; and increases again when the reversal rotations continue to increase. This phenomenon is thought to be due to the geometrically necessary dislocation (GND) density which decreases during the inverse straining. This study introduces concepts of the solute-defect complexes and the multiple local interaction energies between solute and dislocations to explain the strengthening mechanisms. The understanding of the HPT processing and microstructural modification has been enhanced through construction of models.

620.1

QC Physics ; T Technology (General)

Quantum well intermixing in 1.55 um InGaAs/AlInGaAs and InGaAs/InGaAsP structures and applications

Liu, Xuefeng

January 2002

The work described in this thesis is aimed at the exploring the possibility of optically integrating multi-bandgap energy devices on appropriate semiconductor substrates, using the technology of quantum well intermixing. A novel quantum well intermixing technique, based on sputtering process induced disordering (SID), has been developed for the first time, addressing multi-bandgap active device integration. Using this technique, blue shifts have been precisely tuned from 0 nm to over 160 nm for the InGaAs/AlInGaAs and from 0 nm to 100 nm for the InGaAs/InGaAsP MQW systems. Assessment of post-process material characteristics has shown that good electrical and optical qualities were maintained in the bandgap widened regions of both the InGaAs/AlInGaAs and InGaAs/InGaAsP material systems. This novel technique has been used to create multi-wavelength light sources that are of potential application in WDM systems and 2x2 crosspoint optical integrated switches. The expected performance has been achieved. A reactive ion etching process, using CH4/H2 etching gas, has been investigated, particularly for effective etching in the InGaAs/AlInGaAs MQW system. A 'standard' process for the InGaAs/AlInGaAs material system has been developed, based on experimental research. Modelling and design of 3-dB MMI couplers have been carried out. An improved Ti/Si02 mask for reactive ion etching has been successfully employed to ensure the waveguide profiles of fabricated MMI couplers meet the design specification, especially regarding the lateral profiles of the MMI section. Characterisation has shown the waveguide profile is close to the design requirement (side wall angle is of 81±2°). The principle operation of the so-called terahertz optical asymmetric demultiplexer has been qualitatively described and the design of a Mach-Zehnder interferometer (MZI) type demultiplexer has been carried out. Three kinds of MZI demultiplexers with different geometric structures have been fabricated using SID technique. Assessment of the devices has been carried out, including the operation of semiconductor amplifier, propagation loss of the device, etc.

621.38152

QC Physics : T Technology (General)

Lorentz TEM characterisation of magnetic and physical structure of nanostructure magnetic thin films

Ngo, Duc-The

January 2010

The work presented in this thesis is an investigation which aims to quantitatively characterise the physical microstructure, magnetic structure and micromagnetic behaviour of nanostructured thin films for magnetic recording and spintronics application. The nanostructures in the present work involve continuous and patterned thin films. Chapters 1, 2, and 3 present the overview backgrounds directly relevant to the work. Chapter 4 focuses on vortex structure in magnetic nanodots. The results confirm that the behaviour of the vortex can be modified by changing the edge geometry of the dots. It is demonstrated a practical method to determine the out-of-plane component of the vortex core with high accuracy and speed. Additionally in-plane curling magnetisation of the vortex is also mapped by reconstructing the electron phase using the transport-of-intensity equation. However this method is susceptible to spurious low spatial frequency and this aspect is explored to show limitations of the method. Chapter 5 deals with the characterisation of magnetic structure in nanoconstrictions intended to trap domain walls (DWs) in the nanoconstrictions. A structure was fabricated with two micron-sized pads as the sources for creation of DWs. A DW can be driven to be pinned at the nanoconstriction resulting in a change of magnetoresistance due to the contribution of the DW to the resistance of the device. The magnetisation configuration around the constriction is studied during the reversal process. It is apparent that that understanding the magnetisation rotation around the constriction and into the pads is the key to the magnetoresistance measurements and the DW resistance is part of this process. Evidences of DW compression at the nanoconstriction were noted. In Chapter 6 the investigation of the physical structure and micromagnetism of CoIr film is described. A hexagonal crystal structure with a [0001] texture normal to the film plane was characterised. Weak anisotropy is observed in the film denoted by a complex reversal on the hard axis due to incoherent rotation of magnetic moments. The film exhibits typical soft magnetic behaviour it merits compared to other soft materials are discussed in light of the results obtained here. Chapter 7 concludes with a discussion of the outcomes of the present thesis. Additionally possible directions for future research in topics discussed in this thesis are proposed.

530.412

Eta photoproduction study with the upgraded Glasgow tagger at MAMI

McNicoll, Eilidh F.

January 2010

Photoproduction of mesons provides an excellent means by which to study the proton excitation spectrum. The existence and properties of some nucleon resonances are well established, but many more are still debated, meriting much theoretical and experimental attention. The proximity and widths of such excited states result in difficulties in separating contributions from individual resonances. However, the S_11(1535) is the only state in the second resonance region to couple strongly to an Nη final state. Consequently, η production provides clean selection of this S_11 intermediate state, for incident photons in the energy range 700 to 1400MeV. The S_11(1535) is a well-established resonance, but its composition is a contentious topic, requiring further experimental data to distinguish between competing theories. The MAMI electron accelerator was upgraded in 2006 to increase its maximum beam energy from 885 to 1508MeV. The A2 collaboration use tagged Bremsstrahlung to produce the necessary photons for photoproduction experiments. The upgrade granted access to the second resonance region of the proton excitation spectrum, which covers the centre-of-mass energy range 1.3 < W < 1.6GeV. This exceeds the η production threshold of W = 1485MeV (Eγ = 707MeV) and encompasses the full width of the S_11(1535). For exclusive measurements of η photoproduction, a reasonably precise knowledge of the incident photon energy is required. This is provided for the A2 collaboration by the Glasgow Photon Tagging Spectrometer (the “tagger”). The upgrade of MAMI necessitated the corresponding upgrade of the tagger. The work of this thesis included assisting in the upgrade and calibration of the tagger before using the completed spectrometer in the measurement of differential cross-sections of η photoproduction on the proton from threshold to 1403MeV incident photon energy. The agreement of this analysis with previous experiments demonstrates the success of both upgrade and calibration.

531.16

Asteroseismology of β Cephei and Be type stars

Goss, Kym Jeanette Frances

January 2012

The thesis focuses on the asteroseismology of main sequence B-type stars, particularly β Cephei and Be stars. Photometric observations of these stars were analysed in order to detect stellar oscillations. The photometric data analysed in this thesis were collected using the Solar Mass Ejection Imager (SMEI). The analysis initially focussed on known β Cephei stars, to refine information on previously detected frequencies and detect further oscillations. A survey was then conducted using data from the SMEI instrument to search for further β Cephei stars. The results from this survey were analysed, and individual stars were examined in more detail which may possibly be β Cephei like. Due to the long duration of light curves obtained with the SMEI instrument, stellar oscillations can be analysed for evidence of amplitude and phase change. This type of analysis was completed on two Be stars, Achernar and \(\zeta\) Oph, and significant amplitude changes in the oscillations of both of these stars were detected. There is evidence that the amplitude variations may be linked with the outburst events that occur on Be stars, and therefore this analysis may be used to help solve the puzzle of the Be phenomenon.

500

The development of metasurfaces for manipulating electromagnetic waves

Kenney, Mitchell Guy

January 2016

The work outlined in this thesis focuses on the development and fabrication of metasurfaces for manipulating electromagnetic waves, with the potential for applications in imaging and holography. Metasurfaces are the Two-Dimensional counterpart of metamaterials, which are artificial materials used to invoke electromagnetic phenomena, not readily found in nature, through the use of periodic arrays of subwavelength ‘meta-atoms’. Although they are a new and developing field, they have already secured a foothold as a meaningful and worthwhile focus of research, due to their straight-forward means of investigating fundamental physics, both theoretically and experimentally - owing to the simplicity of fabrication - whilst also being of great benefit to the realisation of novel optical technologies for real-world purposes. The main objective for the complete manipulation of light is being able to control, preferably simultaneously, the polarisation state, the amplitude, and the phase of electromagnetic waves. The work carried out in this thesis aims to satisfy these criteria, with a primary focus on the use of Geometric phase, or Pancharatnam-Berry phase. The first-principles designs are then used to realise proof-of-concept devices, capable of Circular Conversion Dichroism; broadband simultaneous control of phase and amplitude; and a high-efficiency, broadband, high-resolution hologram in the visible-to-infrared.

539.2

Precision interferometry in a new shape : higher-order Laguerre-Gauss modes for gravitational wave detection

Fulda, Paul

January 2012

The sensitivity of the next generation of interferometric gravitational wave detectors will be limited in part by thermal noises of the optics. It has been proposed that using higher-order Laguerre-Gauss (LG) beams in the interferometers can reduce this noise. This thesis documents progress made in assessing the compatibility of higher-order LG beam technology with the existing precision interferometry framework used in the gravitational wave detector community. A numerical investigation was made into techniques for generating higher-order LG modes with a phase modulating surface. The optimal conditions for mode conversion were determined using fast Fourier transform (FFT) simulations, and predictions were made for the mode purity achievable with this method. Table-top experiments performed at Birmingham demonstrated the generation of higher-order LG modes using a spatial light modulator, and showed for the first time the feedback control of an optical cavity on resonance for higher-order LG modes. An increase in the purity of LG\(_{33}\) modes from 51% to over 99% upon transmission through the cavity was shown. Investigations were carried out at the Glasgow 10m prototype detector into the performance of the LG\(_{33}\) mode in a suspended 10m cavity, providing useful insights into the compatibility of LG modes with larger scale interferometers.

520

Quasi-classical theory of weakly anisotropic superconductors

Smith, Mark James

January 2012

This thesis starts by reviewing superconductivity in one-dimension where fluctuations cause a loss of supercurrent due to an intrinsic resistance. Solved via the Ginzburg-Landau equations, the theory of thermally activated phase slips given by Langer and Ambegaokar is outlined. In turn this leads to the investigation of superconductivity via a microscopic approach, in particular the quasi-classic green’s functions of Eilenberger. The Eilenberger equations are derived and considered in the dirty and weakly anisotropic limits which provides a simple derivation of the Ginzburg-Landau equations near the transition temperature. This prompts an extended derivation which includes the non-linear terms normally removed in deriving the Ginzburg-Landau equations. This is required for calculating effects at temperatures below the transition temperature. These quasi-classic equations of weakly anisotropic superconductors are first written for arbitrary temperature and impurity concentration then limited to the pure and dirty cases. The latter being simplified to zero temperature and solved in the context of thermally activated phase slips.

537.623

Engineering of demagnetisation fields in exchange biased antidots studied using ferromagnetic resonance and Lorentz microscopy

Trindade Gonçalves, Francisco José

January 2015

Nanostructured ferromagnetic materials have gained considerable attention recently for use in novel devices in the areas of data storage, microwave signal processing and propagation of electromagnetic waves. Structural modifications allow a control over the internal magnetic properties of the system down to the nanoscale. Lateral confinement gives rise to a distribution of demagnetisation fields in the plane of the thin film which can create interesting effects on static and dynamic magnetic properties. In the context of this dissertation, nanostructuring is used as a means to engineer the static and dynamic response of magnetic systems. In particular, periodic arrays of holes embedded in continuous films are studied. With patterning one observes the emergence of an anisotropic field dependence as well as the emergence of non-uniform spin precession modes due to the dipole distribution at the film interfaces. These properties were probed primarily using a technique called broadband ferromagnetic resonance, whereby a microwave field drives the local spin dynamics of the magnetic system. A way to further modify the magnetic properties induced due to the symmetry of the periodic structuring is by introducing an unidirectional field contribution which is characteristic of an exchange biased system. It was found that the magnetic pole distribution in antidots is particularly sensitive to the effects of exchange bias, giving rise to an asymmetric frequency response with respect to the applied field. The asymmetric microwave properties of an exchange biased FeMn/NiFe system with antidot structuring, obtained using electron beam lithography, are investigated. The ferromagnetic resonance (FMR) spectra exhibited several magnetostatic spin wave modes with 8-fold and 4-fold anisotropy components. Moreover, it was observed that large frequency asymmetries are obtained along the directions 10 degrees off the main antidot lattice axes, as result of the competing anisotropies. Brillouin light scattering measurements showed the presence of a magnonic band gap as expected for this type of structure. To interpret these observations, the spin precessional modes obtained experimentally are correlated with localised mode profiles obtained by micromagnetic simulations. This hybrid structure is a good candidate for applications such as selective microwave filtering and for use in multi-state magnetic logic. The prospects of using patterned exchange biased systems to engineer microwave properties is greatly increased if one goes beyond the 2-dimensional perspective. In multilayered structures, one can modify the magnetic properties layer-by-layer to achieve the desired response. This concept is demonstrated here by using a three dimensional structure in which an exchange biased and a free magnetic layer are stacked upon one another and patterned with an antidot configuration. The exchange bias acts as a pinning field for one layer, while the free layer reverses, promoting a zero net moment state. Interlayer dipole interactions are found to result in the partial cancellation of the microwave response. Micromagnetic simulations support the existence of a diminished microwave response which was confirmed by FMR measurements of an equivalent structure. The net moment cancellation, indicative of the antiparallel alignment, was observed on a Lorentz differential phase contrast scanning transmission electron microscope equipped with an FMR probe, which was designed and built for the purpose. This unique tool allows access to complex microwave response while the ground state of a nanostructured film is imaged via Lorentz microscopy. From the magnetostatic viewpoint, our results differ greatly from previous studies in a way that this sample shows distinct magnetic history and the near remanence states exhibit unique magnetic textures: magnetic vortices. The applicability of the TEM in-situ FMR probe was extended to the mapping of radio frequency electromagnetic (EM) fields using low angle diffraction (LAD) imaging. The electron beam, propagating in a sample free environment, experiences the field distribution generated by the microstrip waveguide, which alters the electron amplitude and phase, as described by the Aharonov-Bohm effect, and results in different intensity profiles at the detector. As the microwave frequencies were varied, the different polarisation states are imaged directly. Microwave simulations allowed the EM field distribution to be calculated, which was used to reproduce the LAD results. A knowledge of the near field distribution in antennas is often a challenging task so this technique opens up new opportunities for planar devices operating in high vacuum conditions.

538

Distributed development of large-scale distributed systems : the case of the particle physics grid

Kyriakidou-Zacharoudiou, Avgousta

January 2011

Developing a Grid within High Energy Physics for the Large Hadron Collider particle accelerator is characterised as a highly collaborative, distributed and dynamic systems development effort. This research examines the way this distributed Grid is developed, deployed and provided as a service to the thousands of physicists analysing data from the Large Hadron Collider. The particle physics community has always been at the forefront of computing with a tradition of working in large distributed collaborations, therefore providing a "distinctive" case of distributed systems development practice. The focus of concern is the collaborative systems development practices employed by particle physicists in their attempt to develop a usable Grid. The research aims to offer lessons and practical recommendations to those involved in globally distributed systems development and to inform the information systems development literature. Global software development presents unaddressed challenges to organisations and it is argued that there is an urgent need for new systems development practices and strategies to be created that can facilitate and embrace the rapid changes of the environment and the complexities involved in such projects. The contribution of the study, therefore, is a framework of guidance towards engendering what the author defines as "Hybrid Experimental Agile Distributed Systems Development Communities" revealing a set of dynamic collaborative practices for those organisational contexts engaged in distributed systems development. The framework will allow them to reflect on their own practice and perhaps foster a similarly dynamic flexible community in order to manage their global software development effort. The research is in the form of an interpretative qualitative exploratory case study, which draws upon Activity Theory, and frames the Grid's distributed development activity as a complex overarching networked activity system influenced by the context, the community's tools, rules, norms, culture, history, past experiences, shared visions and collaborative way of working. Tensions and contradictions throughout the development of this Grid are explored and surfaced, with the research focusing on how these are resolved in order for the activity system to achieve stability. Such stability leads to the construction of new knowledge and learning and the formation of new systems development practices. In studying this, practices are considered as an emergent property linked to improvisation, bricolage and dynamic competences that unfold as large-scale projects evolve.

539.7