Global ETD Search

91	Un microscope de champ magnétique basé sur le défaut azote-lacune du diamant : réalisation et application à l'étude de couches ferromagnétiques ultraminces / A magnetic field microscope based on the nitrogen-vacancy defect in diamond : realisation and application to the study of ultrathin ferromagnets Tetienne, Jean-Philippe 13 November 2014 (has links) La capacité à cartographier le champ magnétique à l'échelle nanométrique serait un atout crucial pour étudier les propriétés magnétiques des solides ainsi que certains phénomènes de transport, mais aussi pour des études fondamentales en biologie. Cette thèse porte sur la réalisation d'un microscope de champ magnétique d'un genre nouveau, qui promet une résolution spatiale de quelques nanomètres, une sensibilité de l'ordre du nanotesla, et fonctionne aux conditions ambiantes. Ce microscope est basé sur le défaut azote-lacune du diamant, dont les propriétés quantiques peuvent être exploitées pour en faire un magnétomètre ultrasensible de taille atomique. Dans un premier temps, nous présenterons le fonctionnement et la réalisation du microscope à défaut azote-lacune, qui consiste essentiellement en un microscope à force atomique sur la pointe duquel un nanocristal de diamant est attaché. Nous testerons le microscope en imageant le champ de fuite généré par un cœur de vortex dans un microdisque ferromagnétique. Dans un second temps, nous appliquerons le microscope à l'étude de couches ferromagnétiques ultraminces. Ces systèmes présentent un intérêt à la fois fondamental, les effets d'interfaces restant encore largement inexplorés à ce jour, et technologique, puisqu'ils sont à la base de propositions pour la réalisation de nouvelles mémoires magnétiques à basse consommation d'énergie. Nous étudierons d'abord la nature des parois de domaines dans ces couches ultraminces, ce qui nous permettra de révéler l'existence d'une interaction Dzyaloshinskii-Moriya d'origine interfaciale dans certains échantillons. Nous étudierons ensuite les sauts nanométriques d'une paroi de domaine induits par l'agitation thermique. Nous démontrerons en particulier le contrôle de ces sauts par un laser, ce qui nous permettra de visualiser et explorer le paysage énergétique de la paroi. / The ability to map the magnetic field at the nanometer scale would be a crucial advance to study the magnetic properties of solids as well as some transport phenomena, but also for fundamental studies in biology. This thesis deals with the realisation of a magnetic field microscope of a new kind, which promises a spatial resolution down to a few nanometres, a sensitivity of the order of a few nanoteslas, and operates under ambient conditions. This microscope is based on the nitrogen-vacancy defect in diamond, whose quantum properties can be harnessed to make an ultrasensitive, atomic-size magnetometre. In the first part, we will present the basic principles and the realisation of the nitrogen-vacancy defect microscope, which consists essentially in an atomic force microscope on the tip of which a diamond nanocrystal is grafted. We will test the microscope by imaging the stray field generated by a vortex core in a ferromagnetic microdisk. In the second part, we will apply the microscope to the study of ultrathin ferromagnets. These systems are interesting both from the physical point of view, as interface effects have been little explored so far, and for technology, as they are the cornerstone of several proposals for realising novel magnetic memory devices with low energy consumption. We will first study the nature of domain walls in these ultrathin ferromagnets, which will enable us to reveal the existence of an interface-related Dzyaloshinskii-Moriya interaction in some samples. Next, we will study the nanometric jumps of a domain wall induced by thermal fluctuations. In particular, we will demonstrate control over these jumps using a laser, which will allow us to visualise and explore the wall's energy landscape. Couche ultramince Imagerie magnétique Magnétométrie Microscopie à sonde locale Nanodiamant Nanomagnétisme Interaction Dzyaloshinskii-Moriya Ultrathin films Magnetic imaging Magnetometry Scanning probe microscopy Nanodiamond Nanomagnetism Dzyaloshinskii-Moriya interaction
92	Caractérisation mécanique des matériaux élastiques à l'échelle locale par microscopie à pointe vibrante : Approche multimodale et mesure de champs / Mechanical characterization of elastic materials at local scale using vibrating tip acoustic microscopy : Multimodal approach and full-field measurement Travaillot, Thomas 14 May 2014 (has links) Ces travaux de thèse proposent une amélioration du Scanning Microdeformation Microscope (SMM),un microscope à sonde locale, pour la caractérisation mécanique élastique des matériaux à l’échellelocale. Il est montré qu’en utilisant n > 2 modes de résonance du SMM, il est possible de découplerles mesures du module de Young et du coefficient de Poisson d’un matériau isotrope.Une étude des modes du résonateur a permis d’enrichir son modèle afin qu’il puisse modélisern > 2 modes. Des procédures ont été développées pour identifier les paramètres de ce modèle etles constantes élastiques des matériaux à partir de n > 2 fréquences de résonance. Enfin, ces procéduresont été appliquées à des exemples de caractérisation à l’échelle locale afin de valider laméthode et d’en exhiber les possibilités et les limites.Pour gagner en robustesse et se diriger vers la caractérisation des matériaux anisotropes, un systèmed’imagerie interférométrique en lumière polarisée, permettant la mesure du champ de rotationde surfaces réfléchissantes dans une direction particulière, a été développé pour être intégré auSMM. Son prisme biréfringent à gradient uniaxial d’indice lui confère sa sensibilité à la rotation. Cesystème est capable de mesurer un champ de rotation localisé comme c’est le cas au voisinage dela pointe du SMM. Il a aussi montré son intérêt dans les cas où l’effet d’échelle rend particulièrementintéressante la mesure de la rotation. / This work proposes an improvement of the Scanning Microdeformation Microscope (SMM), a scanningprobe microscope, for the mechanical elastic characterization of materials at local scale. It demonstratesthat using n > 2 SMM resonance frequencies allows to decouple Young’s modulus andPoisson’s ratio values for an isotropic material.The mechanical description of the resonator has been enriched in order to allow for an accuratemodeling over a wide frequency range. Procedures have been developed to identify the modellingparameters and the elastic constants of the materials from n > 2 resonant frequencies. Finally, theseprocedures have been applied to the characterization of various materials at local scale in order tovalidate the method and to present possibilities and limits.To improve robustness and move towards the characterization of anisotropic materials, a polarizedlightimaging interferometer was developed to measure the rotation field of reflecting surfaces in aparticular direction. The sensitivity to the rotation originates from a homemade birefringent prism withuniaxial gradient of refractive index. This system is able to measure a localized rotation field as it isinduced in the vicinity of the tip of the SMM. Its interest is also demonstrated in cases in which scaleeffects make the rotation measurement preferable to the out-of-plane displacement measurement. Microscopie à sonde locale Scanning Microdeformation Microscope Caractérisation mécanique Imagerie interférométrique Scanning probe microscopy Scanning Microdeformation Microscope Mechanical characterization Interferometric imaging 621.3
93	Využití měřicí metody SPM v technologii výroby krystalických solárních článků / The Use of AFM Measurement Method in Crystalline Silicon Solar Cells Technology Mojrová, Barbora January 2013 (has links) This thesis deals with the use of Atomic Force Microscopy (AFM) and Kelvin Probe Force Microscopy (KPFM) in solar cells production. Both techniques measure surface properties using interactions between surface and tip that progressively scans entire surface of the sample. Atomic force microscopy allows three dimensional imaging of surface structure. Kelvin probe force microscopy is used to measure the contact potential difference on the sample surface. There are described experimental measurements of monocrystalline and multicrystalline substrates after various etching processes using AFM. By using KPFM the contact potential difference was measured on dielectric layers PSG, SiOX, SiNX and Al2O3 and on selective emitter structures. All experiments described in this work were carried out at the Solartec Ltd. workplace and they completely correspond with the actual technology of crystalline solar cells production.
94	Contrôle de l'orientation de molécules pour la réalisation de nanosources de lumière / Control of the orientation of molecules towards the realization of nanosources of light Hsia, Patrick 25 November 2015 (has links) Ce travail concerne le développement d’un nouveau type de microscopie optique en champ proche (SNOM) basé sur la mise en œuvre de sondes dite actives qui utilisent le signal de génération de seconde harmonique (SHG) d’un petit nombre de molécules orientées. L’orientation de ces molécules est obtenue par l’application d’un champ électrique statique dans une jonction constituée d’une pointe métallique effilée placée à proximité d’un substrat conducteur et immergée dans une solution de molécules dipolaires non-linéaires. L’excitation laser de ces molécules localement orientées permet d’obtenir une polarisation non-lineaire à fréquence double qui constitue une nanosource de lumière intrinsèquement localisée et pouvant interagir avec le champ proche du substrat. Nous nous sommes intéressés à l’imagerie de nano-objets lithographiés par cette technique de SNOM-SHG. Nous avons pu démontrer la possibilité d’obtenir une résolution de l’ordre de 200 nm, soit une résolution meilleure d’un facteur 2 par rapport à la limite de diffraction.Nous avons ensuite étudié les moyens d’optimiser les performances de ce nouveau type de sondes SNOM-SHG. Une voie consiste à exploiter les propriétés d’antenne optique de pointes métalliques effilées, qui peuvent être le siège d’effets d’exaltation du champ électromagnétique résultant de la singularité géométrique de ces objets (extrémité effilée) ou de l’excitation de résonances plasmons. Afin de pouvoir quantifier ces effets, nous avons entrepris la caractérisation, par luminescence à 2 photons (TPL), de nanofils d’or considérés comme objets de référence pour mimer une pointe. Des fils lithographiés ainsi que des fils issus de chimie colloïdale ont été étudiés de façon à mieux comprendre à la fois l’influence de la forme et de la cristallinité des objets sur les exaltations de champ. Des études simultanées de la géométrie et des propriétés optiques d'un nanofil unique ont été menées au moyen d'un microscope optique inversé associé à une excitation laser et couplé à un microscope à force atomique (AFM) dont la pointe est préalablement réglée pour coïncider avec le spot laser. En balayant l’échantillon, nous pouvons directement confronter l’image topographique de l’objet à la cartographie de points chauds enregistrés à sa surface, le signal de TPL étant directement corrélé à la densité locale d’états électromagnétiques. Nous avons pu montrer que les fils lithographiés et les fils colloïdaux présentaient des facteurs d’exaltation locale de champ différents, la cristallinité des objets pouvant aussi être révélée que via l’analyse spectrale du signal de TPL émis. Enfin, un dernier volet important de mon travail a consisté à faire évoluer le banc expérimental précédemment développé au laboratoire de façon à pouvoir réaliser simultanément des caractérisations de type SNOM-SHG et des caractérisations topographiques. Dans ce but, nous avons travaillé à l’intégration d’une tête AFM diapason sur notre banc de microscopie non-linéaire. Au-delà des aspects électroniques liés à l’optimisation du fonctionnement de ce diapason, le couplage du faisceau laser dans le microscope a également été entièrement reconfiguré. / This work deals with the development of a new kind of scanning near-field optical microscopy (SNOM) based on the realization of so-called active probes taking advantage of the second harmonic generation (SHG) signal coming from a few oriented molecules. The orientation of these molecules is obtained by applying a static electric field in a junction made of a sharp metallic tip placed close to a conductive substrate and immersed in a solution containing dipolar non-linear molecules. A second order nonlinear polarization is obtained from these locally oriented molecules following their excitation with a laser beam finally leading to a nanosource of light intrinsically localized and able to interact with the near-field of the substrate.We have investigated this SNOM-SHG technique to image nano-objects made by e-beam lithography. We were able to demonstrate that a resolution of about 100 nm could be reached, which appears better (of a factor2) than the diffraction limit.We have then been focusing on the way to improve the capabilities of this new type of SNOM-SHG probes. One approach consists in taking advantage of the optical antenna effects that can occur at the end of sharp tips, where the electromagnetic field can be enhanced due to geometrical effects (sharp extremities) or due to the excitation of plasmon resonances. In order to quantify these field enhancements, we have carried out the characterization of gold nanowires using two-photon luminescence (TPL) ; considering these wires as reference objects that can mimic tips. Nanowires made by e-beam lithography and nanowires synthesized by colloidal chemistry have both been studied in order to have a better understanding of the influence of the shape and the crystallinity on the field enhancements. Simultaneous analysis of the geometry and the optical properties of a single nanowire has been carried out using an inverted microscope associated to a laser excitation and coupled to an atomic force microscopy (AFM) which tip is previously aligned with the laser spot. When scanning the sample, we can directly correlate the topographic image of the object to the mapping of the hotspots recorded on its surface, the TPL signal being directly linked to the electromagnetic local density of states. We were able to evidence that both nanowires made by e-beam lithography or synthesized by colloidal chemistry exhibit different field enhancement factors, the crystallinity of the objects being also revealed following the spectral analysis of the emitted TPL signal.Finally, a last important part of my work has dealt with the evolution of the experimental setup previously developed in the laboratory in order to be able to achieve simultaneously SNOM-SHG type and topographic characterizations. We have therefore been working on the integration of an AFM tuning fork head to our nonlinear optical bench. Above the electronic aspects related on the optimization of the tuning fork implementation, the coupling of the laser beam in the microscope has also been reconfigured. Optique de champ proche Plasmonique Microscopie à sonde locale Génération de seconde harmonique Nanofils d'or Diapason Near-Field optics Plasmonics Scanning probe microscopy Second Harmonic Generation Gold nanowires Tuning fork
95	Optical Properties of Individual Nano-Sized Gold Particle Pairs: Mie-Scattering, Fluorescence, and Raman-Scattering Olk, Phillip 15 July 2008 (has links) This thesis examines and exploits the optical properties of pairs of MNPs. Pairs of MNPs offer two further parameters not existent at single MNPs, which both affect the local optical fields in their vicinity: the distance between them, and their relative orientation with respect to the polarisation of the excitation light. These properties are subject of three chapters: One section examines the distance-dependent and orientation-sensitive scattering cross section (SCS) of two equally sized MNPs. Both near- and far-field interactions affect the spectral position and spectral width of the SCS. Far-field coupling affects the SCS even in such a way that a two-particle system may show both a blue- and redshifted SCS, depending only on the distance between the two MNPs. The maximum distance for this effect is the coherence length of the illumination source – a fact of importance for SCS-based experiments using laser sources. Another part of this thesis examines the near-field between two MNPs and the dependence of the locally enhanced field on the relative particle orientation with respect to the polarisation of the excitation light. To attain a figure of merit, the intensity of fluorescence light from dye molecules in the surrounding medium was measured at various directions of polarisation. The field enhancement was turned into fluorescence enhancement, even providing a means for sensing the presence of very small MNPs of 12 nm in diameter. In order to quantify the near-field experimentally, a different technique is devised in a third section of this thesis – scanning particle-enhanced Raman microscopy (SPRM). This device comprises a scanning probe carrying an MNP which in turn is coated with a molecule of known Raman signature. By manoeuvring this outfit MNP into the vicinity of an illuminated second MNP and by measuring the Raman signal intensity, a spatial mapping of the field enhancement was possible. / Diese Dissertation untersucht und nutzt die optischen Eigenschaften von Paaren von Metall-Nanopartikeln (MNP). MNP-Paare bieten gegenüber einzelnen MNP zwei weitere Parameter, welche beide auf das optische Nahfeld der zwei MNPs wirken: zum Einen der Abstand der zwei MNPs zueinander, zum Anderen die relative Ausrichtung des Paares bezüglich der Polarisation des anregenden Lichts. Diese Eigenschaften sind Thema der Arbeit: Ein Abschnitt untersucht den abstands- und orientierungsabhängigen Streuquerschnitt (SQS) zweier gleichgroßer MNPs. Die spektrale Position und die Breite des SQS wird von Wechselwirkungen sowohl im Nah- als auch im Fernfeld beeinflusst. Der Einfluß der Fernfeld-Wechselwirkung geht so weit, daß ein Zwei-MNP-System sowohl einen blau- als auch einen rotverschobenen SQS haben kann – dies hängt lediglich vom Abstand der zwei MNPs ab. Die Reichweite dieser Fernfeld-Wechselwirkung wird durch die Kohärenzlänge der Beleuchtungsquelle bestimmt – eine wichtige Tatsache für SQS-Untersuchungen, welche Laserquellen verwenden. Ein weiterer Teil der Dissertation untersucht das Nahfeld zwischen zwei MNPs. Insbesondere wird dargestellt, inwieweit die Überhöhung des Nahfelds von der Orientierung des Partikelpaares bezüglich der Polarisation des Anregungslichts abhängt. Um den Effekt quantifizieren zu können, wurde die Intensität der Fluoreszenz des umgebenden Mediums für verschiedene Polarisationsrichtungen gemessen. Die lokale Feldverstärkung konnte in eine Fluoreszenzverstärkung gewandelt werden, mit deren Hilfe sich sogar die Anwesenheit sehr kleiner MNPs von nur 12 nm Durchmesser nachweisen ließ. Wie Nahfeld-Intensitäten experimentell quantifiziert werden können, stellt ein dritter Abschnitt dieser Dissertation vor – per MNP-verstärkter Raman-Rastersonden-Mikroskopie. Diese Technik besteht aus einer Rastersonde, welcher ein MNP anheftet, welches wiederum mit einem Molekül bekannter Ramansignatur überzogen ist. Indem solch eine Sonde in die unmittelbare Nähe eines zweiten, beleuchteten MNPs gebracht wurde und dabei die Intensität des Raman-Signals aufgezeichnet wurde, ließ sich die räumliche Verteilung der Ramanverstärkung vermessen. info:eu-repo/classification/ddc/530 ddc:530
96	ULTRAFAST NANOSCALE PATTERNING SYSTEM: SURFING SCANNING PROBE LITHOGRAPHY Bojing Yao (12456495) 25 April 2022 (has links) <p> </p> <p>The development of the semiconductor industry is encountering a giant leap recently as Moorse’s is extended to the next levels. Advanced nanomanufacturing technology is the major challenge in the way. Higher resolution down to a few nanometers as well as higher throughput is always the key. As the optical lithography determines the feature size, the photomask is still in need of a low-cost and high resolution maskless patterning tool. In another aspect, the growing information allows the generation and storage of data at ever faster rates, which has led to the era of big data reaching a heroic amount of 7 zettabytes of total data in 2020. Future growth requires the total shipment of data storage capacity to double roughly every two years or less. For the future generation of magnetic data storage, the bit patterned medium (BPM) in combination with the current heat assisted magnetic recording (HAMR) is expected to increase the areal storage capacity by another order of magnitude by physically isolating magnetic bits at the nanoscale. Electron beam lithography (EBL) as a universal maskless lithography technique shows great resolution but has a high tool cost and low process throughput. Scanning probe lithography (SPL) is another family of nanoscale patterning techniques with low tool cost but the practical throughput is still limited. For example, dip pen nanolithography utilizes an AFM probe as a writing pen in direct patterning, but the ink delivery is limited by the rate of ink’s capillary transport. Other SPLs such as thermal probes with capabilities of 3D fabrication and surface oxidation via chemical reactions are all facing similar limitations in throughput. One way of breaking this limitation is to use parallel writing with millions of probes which also faces uniformity problems. </p> <p>In this Ph.D. dissertation, we report our Surfing Scanning Probe lithography (SSPL) method which can boost the scanning speed of SPL by several orders of magnitudes at a low cost by using a hydro-aero-dynamic scanning scheme. We use a homemade patterning head to continuously scan over a partially-wet spinning substrate at a linear speed of meters per second. The head carries several metallic tips which emit electrons and induce electrochemical reactions inside a gap of 10 nm scale. We use a liquid phase precursor and deliver it using the near-field electrospinning method and microfluid structures during the fast patterning. The best linewidth demonstrated is about 15 nm in full-width half maximum (FWHM) which can be further improved using smaller scanning gaps and sharp probe tips. Besides direct writing with a liquid precursor, SSPL can work with gas precursors as well enabled by nano plasma. The rate of material deposition is much high than conventional SPL. The SSPL system is a low-cost nanopatterning technology to produce patterns at high throughput and high resolution.</p> Mechanical Engineering Nanomanufacturing high-throughput nanolithography fast scanning probe air bearing surface hybrid flow electrohydrodynamic nanoplasma nanoscale patterning field emission nano manufacturing nano fabrication
97	Metody SPM založené na sondách vyrobených z křemenného rezonátoru / SPM Methods Based On The Quartz Resonator Probes Wertheimer, Pavel January 2015 (has links) The thesis is focused on development of scanning probe microscope systems, especially development and implementation of quartz resonator probes. The quartz resonator probes, compared to the standard silicon cantilevers, have several advantages. It is in particular their mechanical properties and possibility of direct electrical readout of the deflection signal. Due to the fact, the probes are easy to implement even into more complex SPM systems. The thesis deals with development of universal and open SPM control system electronics. The electronics consist of the commercial SPM control and oscillation units, the development of the other electronic parts (such as the high voltage amplifier and the preamplifier units) is described in the thesis. Further, the thesis reports on development of the qPlus UHV LT SPM microscope system that was carried out at Universität Hamburg. Part of it was development of the qPlus preamplifier able to operate at liquid helium temperature. The third topic of the thesis is the implementation of qPlus technology into the UHV VT SPM microscope suitable to operate in situ with a scanning electron microscope. The qPlus sensors and the universal UHV preamplifier were designed and manufactured. Test measurements were conducted on all of the developed systems.
98	Scanning Probe Microscopy Measurements and Simulations of Traps and Schottky Barrier Heights of Gallium Nitride and Gallium Oxide Galiano, Kevin 07 October 2020 (has links) No description available. Physics Scanning Probe Microscopy Deep Level Transient Spectroscopy SP-DLTS Scanning Tunneling Microscopy Ballistic Electron Emission Microscopy Semiconductors Materials Characterization Finite Element Analysis COMSOL Multiphysics Simulations
99	Near-Field Investigations of the Anisotropic Properties of Supported Lipid Bilayers Johnson, Merrell A. 24 July 2012 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The details of Polarization Modulation Near-Field Scanning Optical Microscopy (PM-NSOM) are presented. How to properly calibrate and align the system is also introduced. A measurement of Muscovite crystal is used to display the capabilities of the setup. Measurements of supported Lβʹ 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) lipid bilayers are presented, emphasizing how it was tooled in exploiting the anisotropic nature of the acyl chains. A discussion of how the effective retardance (ΔS = 2π( n_e-n_o )t/λ) and the direction of the projection of the acyl chains (θ) are measured simultaneously is given, (where t is the thickness of the bilayer and λ is the wavelength of light used). It is shown from ΔS the birefringence (ne-no) of the bilayer is determined, by assuming the acyl chain tilt with respect to the membrane's normal to be ϕ ≈ 32. Time varying experiments show lateral diffusions of ~ 2 x 10-12 cm2/s. Temperature controlled PM-NSOM is shown to be a viable way to determine the main phase transition temperature (Tm) for going from the gel Lβʹ to liquid disorder Lα state of supported DPPC bilayers. A change of ΔS ~ (3.8 +/- 0.3 mrad) at the main phase transition temperature Tm (≈41^o C) is observed. This agrees well with previous values of (ne-no) and translates to an assumed <ϕ> ~ 32^o when T < Tm and 0^o when T > Tm. Evidence of supper heating and supper cooling will be presented, along with a discussion of the fluctuations that occur around Tm. Finally it is shown how physical parameters such as the polarizability are extracted from the data. Values of the transverse (αt) and longitudinal (αl) polarizabilites of the acyl chains are shown to be, αt = 44.2 Å3 and αl = 94.4 Å3, which correspond well with the theoretical values of a single palmitic acid (C16) αt = 25.14 Å3 and αl = 45.8 Å3. Near-Field Scanning Optical Microscopy birefringence Near-field microscopy -- Technique Scanning probe microscopy Anisotropy Refractive index Materials at high temperatures Phospholipids
100	Interactions between spin transport and dynamics studied using spatially resolved imaging and magnetic resonance Page, Michael Roy January 2016 (has links) No description available. Physics magnetism spin transport magnetization dynamics nitrogen vacancy centers in diamond optically detected magnetic resonance ferromagnetic resonance Heusler alloy spin valves graphene spin valves scanning probe microscopy

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