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411	Povećanje ukupnog kočnog momenta magnetoreološke disk kočnice primenom kombinovanog režima rada / Magnetorheological disk brake overall braking torque increase using combined operating mode Poznić Aleksandar 20 May 2017 (has links) <p>U doktorskoj disertaciji razmatra se unapređenje konstrukcije magnetoreolo&scaron;ke disk kočnice sa ciljem povećanja vrednosti ukupnog kočnog momenta. Radi potpunog razumevanja međusobnog odnosa materijala i magnetskog polja na prvom mestu je izvr&scaron;eno utvrđivanje magnetskih svojstava materijala. Unapređenje konstrukcije je izvr&scaron;eno kroz vi&scaron;e iteracija i prototipova. Merenje vrednosti ukupnog kočnog momenta je podeljeno na merenje vi&scaron;e njegovih komponenti pri različitim vrednostima broja obrtaja i upravljačke struje namotaja.</p> / <p>In this thesis magnetorheological disk brake construction improvement is considered, with the goal to increase the overall braking torque value. For purposes of better understanding of material to magnetic field relationship, series of magnetic field testing were conducted. Construction improvement has been carried out through several iterations and different prototypes. Overall braking torque value measurements have been divided into several component measurements, utilizing different rotational speeds and coil control currents.</p>
412	On Spin-inspired Realization of Quantum and Probabilistic Computing Brian Matthew Sutton (7551479) 30 October 2019 (has links) The decline of Moore's law has catalyzed a significant effort to identify beyond-CMOS devices and architectures for the coming decades. A multitude of classical and quantum systems have been proposed to address this challenge, and spintronics has emerged as a promising approach for these post-Moore systems. Many of these architectures are tailored specifically for applications in combinatorial optimization and machine learning. Here we propose the use of spintronics for such applications by exploring two distinct but related computing paradigms. First, the use of spin-currents to manipulate and control quantum information is investigated with demonstrated high-fidelity gate operation. This control is accomplished through repeated entanglement and measurement of a stationary qubit with a flying-spin through spin-torque like effects. Secondly, by transitioning from single-spin quantum bits to larger spin ensembles, we then explore the use of stochastic nanomagnets to realize a probabilistic system that is intrinsically governed by Boltzmann statistics. The nanomagnets explore the search space at rapid speeds and can be used in a wide-range of applications including optimization and quantum emulation by encoding the solution to a given problem as the ground state of the equivalent Boltzmann machine. These applications are demonstrated through hardware emulation using an all-digital autonomous probabilistic circuit. Computer Engineering Computational Physics Nanomagnets Quantum computing Probabilistic Computing Combinatorial Optimization Boltzmann machines
413	Bose-Einstein condensates in coupled co-planar double-ring traps : a thesis presented in partial fulfillment of the requirements for the degree of Masterate of Science in Physics at Massey University, Palmerston North, New Zealand Haigh, Tania J January 2008 (has links) This thesis presents a theoretical study of Bose-Einstein condensates in a doublering trap. In particular, we determine the ground states of the condensate in the double-ring trap that arise from the interplay of quantum tunnelling and the trap’s rotation. The trap geometry is a concentric ring system, where the inner ring is of smaller radius than the outer ring and both lie in the same two-dimensional plane. Due to the difference in radii between the inner and outer rings, the angular momentum that minimises the kinetic energy of a condensate when confined in the individual rings is different at most frequencies. This preference is in direct competition with the tunnel coupling of the rings which favours the same angular momentum states being occupied in both rings. Our calculations show that at low tunnel coupling ground state solutions exist where the expectation value of angular momentum per atom in each ring differs by approximately an integer multiple. The energy of these solutions is minimised by maintaining a uniform phase difference around most of the ring, and introducing a Josephson vortex between the inner and outer rings. A Josephson vortex is identified by a 2p step in the relative phase between the two rings, and accounts for one quantum of circulation. We discuss similarities and differences between Josephson vortices in cold-atom systems and in superconducting Josephson junctions. Josephson vortices are actuated by a sudden change in the trapping potential. After this change Josephson vortices rotate around the double-ring system at a different frequency to the rotation of the double-ring potential. Numerical studies of the dependence of the velocity on the ground state tunnel coupling and interaction strength are presented. An analytical theory of the Josephson vortex dynamics is also presented which is consistent with our numerical results. Josephson vortex tunnel coupling superconductivity
414	A Study of magnetic thin film corrosion mechanisms with the development of a novel on-line coupling technique and with Microstructural and Magnetic Cross-Sectional Profiling Techniques Xu, Danhua 06 1900 (has links) (PDF) Ph.D. / Electrical Engineering / A novel combinatory on-line technique coupling Electrochemistry (EC) with Inductively Coupled Plasma - Mass Spectrometry (ICP-MS) for in-situ quantitative determination of the corrosion mechanism in magnetic thin film structures has been developed in this research. Detailed construction of a system and a comprehensive methodology was described in this dissertation. Uniformly coated multi-layer magnetic thin film samples with multi-elemental alloys containing CoCrPtB and CrMo/Cr on the Ni/P substrate were used in this research for demonstrations. In-situ quantifications conducted in a series of experiments revealed that elemental dissolution was a predominant mechanism during corrosion courses of metallic thin film materials. At the microscopic scale, using results from depletion rate determination as well as cross-sectional analyses of microstructures and magnetic features, elemental passivity was observed to occur, depending on corrosion conditions. Without external influences, surface topographic measurements indicated that passive film could be produced at the macro-scale. The dependence of the dissolution rate of each metallic ion of alloys on electrolyte concentration, potential bias, scanning rate, and corrosion duration suggested that the most critical influential factor in corrosion mechanisms was epitaxial microstructures with strongly-oriented arrangements of grains and grain boundaries. Through the use of cross-sectional microstructural analysis, including high resolution TEM micrography, electron FFT diffraction, and nano-probe with EDS profiling, variations of elemental spatial distributions at grains and grain boundaries due to the corrosion phenomena were discovered, which provided a comprehensive understanding of occurrences of micro-corrosion in thin film structures. Because of the unique magnetic property of magnetic thin films, extensive studies of field strengths from the surface were also performed in this research. Important magnetization variations were noticed when cross-sectional images were obtained. Finally, models of corrosion kinetics in the multiple layers of magnetic thin film structures were proposed.
415	Carbon-based magnetic nanomaterials Zagaynova, Valeria January 2012 (has links) Magnetism of carbon-based materials is a challenging area for both fundamental research and possible applications. We present studies of low-dimensional carbon-based magnetic systems (fullerene-diluted molecular magnets, carbon nanotubes, graphite fluoride, and nanoporous carbon) by means of SQUID magnetometer, X-ray diffraction and vibrational spectroscopy, the latter techniques used as complementary instruments to find a correlation between the magnetic behaviour and the structure of the samples.In the first part of the thesis, characteristic features of the magnetization process in aligned films of carbon nanotubes with low concentration of iron are discussed. It is shown that the magnetism of such structures is influenced by quantum effects, and the anisotropy behaviour is opposite to what is observed in heavily doped nanotubes.In the second part, Mn12-based single molecular magnets with various carboxylic ligands and their 1:1 fullerene-diluted complexes are studied. We prove that magnetic properties of such systems strongly depend on the environment, and, in principle, it is possible to design a magnet with desirable properties. One of the studied compounds demonstrated a record blocking temperature for a single molecular magnet. Both fullerene-diluted complexes demonstrated “magnetization training” effect in alternating magnetic fields and the ability to preserve magnetic moment.The third and the fourth parts of the thesis are dedicated to the analysis of various contributions to the magnetic susceptibility of metal-free carbon-based systems – intercalated compounds of graphite fluorides and nanoporous oxygen-eroded graphite. The magnetic properties of these systems are strongly dependent on structure, and can be delicately tuned by altering the π-electron system of graphite, i. e. by degree of fluorination of intercalated compounds and by introduction of boron impurity to the host matrix of nanoporous graphite. / Magnetism av kolbaserade material är ett utmanande område för både grundforskning och möjliga tillämpningar. Vi presenterar studier med låg-dimensionella kolbaserade magnetiska system (fulleren-utspädda molekylära magneter, kolnanorör, grafit fluorid och nanoporösa kol) med hjälp av SQUID magnetometer, röntgendiffraktion och vibrerande spektroskopi, de senare tekniker som används som komplement instrument för att finna sambandet mellan den magnetiska uppträdande och strukturen hos proven. I den första delen av avhandlingen är egenheter från magnetisering processen i linje filmer av kolnanorör med låg koncentration av järn diskuteras. Det visas att magnetism av sådana strukturer påverkas av kvantmekaniska effekter och anisotropin beteende är motsatsen till vad som observerats i kraftigt dopade nanorör. I den tvåa delen är Mn12-baserade enda-molekyl magneter med olika karboxylsyror ligander och deras 1:1 fulleren-utspädda komplex studeras. Vi visar att magnetiska egenskaperna hos sådana system beror i hög grad på miljön, och i princip är det möjligt att utforma en magnet med önskvärda egenskaper. En av de studerade föreningarna visade en post blockeringstemperaturen för en enda molekylär magnet. Både fulleren-utspädda komplex visade "magnetisering utbildning" effekt i alternerande magnetfält och möjligheten att bevara magnetiskt moment. Den tredje och fjärde delarna av avhandlingen är avsedda för inneboende magnetism av analys av olika bidrag till magnetisk susceptibilitet av metall-fritt kol-baserade system -inskjutna föreningar grafit fluorider och nanoporösa O2-eroderade grafit. Magnetiska egenskaperna hos dessa system är starkt beroende av strukturen, och kan fint avstämmas genom att man ändrar π-elektronsystem av grafit, i. e. med graden av fluorering av inskjutna föreningar och genom införandet av bor föroreningar till värd matris av nanoporösa grafit. carbon nanotube fullerene single molecular magnet Mn12 graphite fluoride nanoporous carbon molecular magnetism magnetic properties SQUID magnetometry x-ray diffraction Raman spectroscopy
416	Study of magnetic properties of nanostructures on self-assembled patterns Malwela, Thomas. January 2010 (has links) In the current study, we give a report when oxalic acid was used as an electrolyte to synthesize an AAO template with hexagonal pore array. Optimum parameters were observed as 0.4 M of oxalic acid, anodizing voltage of 45 V, temperature of approximately 8 Â°C and the period of 120 minutes. Atomic force microscope (AFM) and High resolution scanning electron microscope (HRSEM) showed that template has an average pore diameter of 103 nm. Co and MnOx (x = 1,2) nanostructures were selectively deposited in the pores of the template using a novel atomic layer deposition (ALD) technique. The diameter sizes and the array of the nanostructures and the template were corresponding. Energy dispersive xrays (EDX) and X-ray photoelectron spectroscopy (XPS) confirmed the presence of Co and MnOx (x =1,2) on the samples while x-ray diffraction (XRD) provided an indication of their orientations. Magnetic force microscopy as main characterization tool showed the existence of multi-domains on both Co and MnOx (x =1,2) nanostructures. Self-Assembly Aluminium Anodization Nanopores Electrodeposition Cyclic Voltammetry Co nanostructures MnOx (x = 1,2) nanostructures Nanomagnetism Atomic Force Microscopy Magnetic Force Microscopy Magnetic properties Magnetic domains Domain Walls.
417	Studies On Carbon Nanotubes Hembram, K P S S 05 1900 (has links) The unique electronic, mechanical and physical properties led Carbon nanotubes (CNTs) to be potential candidate for field emitter, hydrogen storage, sensors, nano electronic devices, nano electromechanical systems, polymer composites. In order to make them in the industrial scale we need large quantity production of CNTs with low cost. The present thesis work deals with the preparation of CNTs by pyrolysis method from xylene and further studies on the grown CNTs. Magnetic characterization of CNTs has been done using SQUID. The interaction of CNTs with the microwave irradiation is studied and it was found for the first time that there is light emission from the CNTs apart from direct electric field. In this process we also observed that the static charge develops on the CNTs. A composite of CNTs/DNA has been prepared with varying CNT content and the electrical conductivity measurements have been done. The first chapter of the thesis provides an introduction to carbon family. Carbon nanotubes, which are potential candidates from carbon family, is a growing field for research in science and technology. A glimpse of various methods of preparation of CNTs like arc-discharge, laser ablation, chemical vapour deposition (CVD), hot-filament CVD, plasma enhanced chemical vapor deposition (PECVD), electron cyclotron resonance (ECR PECVD), high-pressure catalytic decomposition of carbon monoxide (HiPCO), pyrolysis are discussed. Some applications of CNTs are also included in this chapter. The second chapter deals with the experimental techniques employed for the preparation of CNTs and their characteristics studied by Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM), X-Ray Diffraction (XRD) and Raman Spectroscopy (RS). The preparation of CNTs from xylene as carbon source and ferrocene as catalyst in pyrolysis method is described in detail. Well aligned CNTs with a length of several tens of micrometers and diameter of 40 to 80 nanometers were obtained as confirmed by SEM. TEM and XRD confirms the graphitic crystal structure of the CNTs. RS also confirms the information about the crystal structure. The third chapter discusses the magnetic studies on CNTs using Superconducting Quantum Interference Device (SQUID) as a function of magnetic field and temperature. In the random mixture of parallel, perpendicular and oblique nanotubes, the applied field produces diamagnetic behavior, although the sample possess different kinds of tubes with various chirality and radii. Paramagnetic deviation was observed on the diamagnetic susceptibility at weak fields and low temperature, confirming qualitatively with the Aharonov-Bhom effect on the energy gap for the magnetic field parallel to the tube axis Chapter four presents the light emission from the CNTs. It describes the light emission from different processes reported in the literature. Here we have observed a new process to generate light from CNTs through microwave irradiation. Along with the light emission some of the tubes get charged and some tubes are physically broken. We provide a simple approach as to why the tubes break and the nature of the breakage is also discussed. The fifth chapter discusses the preparation of CNTs/DNA composites. The conductivity increases with increasing carbon nanotube weight percentage. The increase in conductivity as a function of the CNTs weight percent is attributed to the introduction of conducting CNTs path in the DNA matrix. A summary of the results obtained and the scope for future work are included in the chapter six of the thesis. Carbon - Nanotechnology Carbon - Nanotubes Carbon Nanotubes (CNTs) Carbon Nanotubes - Magnetic Properties Carbon Nanotubes/DNA Composite Carbon Nanotubes - Properties CNTs/DNA Composite Nanotechnology
418	Experimental And Theoretical Studies Of Strongly Correlated Multiferroic Oxides Ghosh, Anirban 03 1900 (has links) (PDF) This thesis presents the synthesis and investigations of physical and chemical properties of multiferroic materials experimentally as well as theoretically. Multiferroics are materials in which at least two of the three ferroic orders, ferroelectricity, ferromagnetism and ferroelasticity occur in the same phase. Multiferroics, have the potential to be used as a four state as well as cross switchable memory devices. The thesis is organized into seven Chapters. Chapter 1 gives a brief overview of the different facets of multiferroics, explaining the origin of Multiferroicity and magnetoelectric coupling, their possible technological applications and the challenges involved. Chapter 2-4 concerns the experimental aspects and chapter 5-7 concerns the theoretical aspects. Chapter 2 deals with experimental investigations on nanoscale charge-ordered rare earth manganites. It shows with decreasing particle size the ferromagnetic interaction increases and the charge-ordering vanishes down to the lowest sizes. Chapter 3 describes magneto-dielectric, magnetic and ferroelectric properties of hexagonal LuMnO3. It also describes the Raman spectroscopy of this compound through the magnetic and ferroelectric transition temperatures. Chapter 4 deals with the anisotropic multiferroic properties in single crystals of hexagonal ErMnO3. In chapter 5 a brief introduction of density functional theory (DFT) is given. Chapter 6 deals with the magneto-structural changes, spin-phonon couplings and crystal field splittings for the different magnetic orderings LuMnO3. Chapter 7 elucidates the role of Lu d0-ness for the ferroelectricity observed of this compound. Multiferroic Oxides Density Functional Theory Rare Earth Manganites Multiferroic Materials Hexagonal Multiferroic Manganites LuMnO3 Materials Science
419	Electron spin resonance studies of frustrated quantum spin systems Kamenskyi, Dmytro 24 June 2013 (has links) (PDF) Since the last few decades frustrated spin systems have attracted much interest. These studies are motivated by the rich variety of their unusual magnetic properties and potential applications. In this thesis, excitation spectra of the weakly coupled dimer system Ba3Cr2O8, the spin-1/2 chain material with distorted diamond structure Cu3(CO3)2(OH)2 (natural mineral azurite), and the quasi-twodimensional antiferromagnet with triangle spin structure Cs2CuBr4 have been studied by means of high-field electron spin resonance. Two pairs of gapped modes corresponding to transitions from a spin-singlet ground state to the first excited triplet state with zero-field energy gaps, of 19.1 and 27 K were observed in Ba3Cr2O8. The observation of ground-state excitations clearly indicates the presence of a non-secular term allowing these transitions. Our findings are of crucial importance for the interpretation of the field-induced transitions in this material (with critical fields Hc1 = 12.5 T and Hc2 = 23.6 T) in terms of the magnon Bose-Einstein condensation. The natural mineral azurite, Cu3(CO3)2(OH)2, has been studied in magnetic fields up to 50 T, revealing several modes not observed previously. Based on the obtained data, all three critical fields were identified. A substantial zero-field energy gap, Δ = 9.6 K, has been observed in Cs2CuBr4 above the ordering temperature. It is argued that contrary to the case for the isostructural Cs2CuCl4, the size of the gap can not be explained solely by the uniform Dzyaloshinskii-Moriya interaction, but it is rather the result of the geometrical frustration stabilizing the spin-disordered state in Cs2CuBr4 in the close vicinity of the quantum phase transition between a spiral magnetically ordered state and a 2D quantum spin liquid. Quantenspinsysteme Austauschwechselwirkung frustriert Systeme Elektronenspinresonanz Grundzustand magnetische Eigenschaften. Quantum spin systems exchange interaction frustrated systems electron spin resonance ground state magnetic properties ddc:530 rvk:UP 6700
420	Optical and MR Molecular Imaging Probes and Peptide-based Cellular Delivery for RNA Detection in Living Cells Nitin, Nitin 10 August 2005 (has links) Detection, imaging and quantification of gene expression in living cells can provide essential information on basic biological issues and disease processes. To establish this technology, we need to develop molecular probes and cellular delivery methods to detect specific RNAs in live cells with potential for in vivo applications. In this thesis work, the major focus is placed on the development of molecular beacons and biochemical approaches (peptides etc.) to deliver such probes to different cellular compartments. These approaches are then employed to study the expression and localization of mRNAs, co-localization of mRNAs with cytoplasmic organelles and cytoskeleton, and co-localization of RNA molecules in the nuclei of living cells. Further along this direction, we were interested in developing a better understanding of the functional states of mRNAs and the fluorescent signal observed in optical imaging experiments. To acheive this goal, we altered the translational process and studied its effect on the detection of mRNAs in living cells. The results of these studies indicate that the translational state of mRNAs favors the hybridization of molecular beacon with its target sequence. This study has also provided the evidence that molecular beacons are reversibly bound to target mRNAs and the repression of the translational process can prevent molecular beacon from binding to its target mRNA. Further, using these approaches in combination with FRAP based biophysical analysis, the dynamics of endogenous RNA in living cells are studied. These studies revealed the possible subcellular organization of RNA molecules and their dynamics in living cells. The results also demonstrated the role of cytoskeleton and ATP in the mobility of specific mRNAs in the cytoplasm. In addition to optical probes, studies have been carried out to develop an MRI contrast agent using iron-oxide nanoparticles for deep tissue molecular imaging. Specifically, we have functionalized magnetic nanoparticles that are water-soluble, mono-dispersed, biocompatible, and easily adaptable for multifunctional bioconjugation of probes and ligands. We have successfully delivered magnetic nanoparticle bioconjugates into live cells and demonstrated their effect on relaxivity. We have further studied the role of coating thickness for optimization of contrast and further enhance the fundamental understanding of contrast mechanisms. Magnetic nanoparticles RNA MRI Optical Molecular beacons Molecular imaging RNA Detection Diagnostic imaging Magnetic resonance imaging Molecular probes Molecular spectroscopy Nanoparticles Magnetic properties

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