MATLAB Simulation to Determine Optimal Design of Thin Films with Embedded Nanoparticles for Optical Heating Applications

Bodette, Julie R.

01 June 2018

No description available.

Chemistry

MATLAB

Simulation

Nanoparticle

TiN

Solar Thermal

A15 stoichiometry and grain morphology in rod-in-tube and tube type Nb₃SN strands; Influence of strand design, heat treatments and ternary additions

Bhatiya, Shobhit

24 August 2010

No description available.

Engineering

Materials Science

Niobium tin superconductors

A Study of Precipitate Morphologies in Cu-Zn and Cu-Zn-Sn Alloys

Malcolm, John

07 1900

The Digitization Centre has determined that page 49 was not published with the original copies of this thesis. / The validity of current theories of precipitate morphology is dependent on the microscopic nature of the precipitate-matrix interface. It is the purpose of this thesis to investigate, by electron microscopy interfacial structure and mobility in precipitation reactions pertaining to these theories. In particular the B->a Widmanstatten reaction in 60:40 brass is investigated and compared with the B->y reaction in a Cu-Zn-Sn alloy. / Thesis / Master of Science (MS)

precipitate morphology

copper

zinc

tin

alloy

Magnetic rotation in the A1̃10 region

Jenkins, David Gareth

January 1999

No description available.

539.7

The electrodeposition of tin coatings from deep eutectic solvents and their subsequent whisker growth

Stuttle, Christopher

January 2014

Tin electrodeposits produced from aqueous electrolytes are frequently used within the electronics industry due to their high solderability and corrosion protection. One limitation to using these deposits is their spontaneous formation of long conductive filament whiskers. These whiskers grow post-electrodeposition and increase the risk of unwanted electrical shorts within electronic devices. In this thesis, tin electrodeposits produced from a proprietary bright acid Tinmac electrolyte, currently used in industry, were studied. Electrodeposits were produced using a range of current densities with and without agitation and were characterised with respect to crystallographic orientation, topography and surface finish. Moreover, the intermetallic compound (IMC) growth produced at the copper substrate-tin coating interface was assessed over a period of time as its growth is considered to be a significant driving force behind whisker formation. In addition, a technique for the electrochemical anodic oxidation of tin electrodeposits on copper substrates was developed. This technique was used throughout this project for the study of IMC growth from tin electrodeposits as it was able to effectively remove the tin whilst leaving the IMCs and substrate unaffected. Ionic liquids exhibit promising electrochemical characteristics for electrodeposition but are still not widely utilised in industry. Their ability to deposit tin coatings has been studied in the present investigation. Trials concentrated on process optimisation to produce uniform electrodeposits by varying current density, SnCl2.2H2O concentration, and electrolyte composition. These deposits were then characterised and compared to tin coatings of similar thickness produced from Tinmac with respect to topography, surface finish, crystallographic orientation, IMC growth, and whisker propensity. Electrodeposits produced from the ionic liquid electrolyte exhibited a different crystallographic texture, topography, and IMC growth compared to those produced from Tinmac. Moreover, the deposit produced from the ionic liquid featured increased whisker growth compared to those produced from Tinmac, but in a wider context, far less growth than conventional tin electrodeposits in the literature. In addition, by exploiting other electrochemical characteristics of ionic liquids, such as their large potential window, future work may be able to produce novel tin or tin alloy electrodeposits which may further reduce the whisker propensity of deposits produced in this investigation.

621.3

"Caracterização do comportamento frente à corrosão de um aço inoxidável austenítico para aplicações biomédicas com revestimentos PVD de TiN, TiCN e DLC" / CHARACTERIZATION OF THE CORROSION BEHAVIOR OF AN AUSTENITIC STAINLESS STEEL FOR BIOMEDICAL APPLICATIONS COATED WITH TiN, TiCN AND DLC PVD COATINGS

Antunes, Renato Altobelli

15 December 2006

Biomateriais metálicos devem apresentar uma combinação de propriedades como resistência à corrosão, biocompatibilidade e resistência mecânica. Os aços inoxidáveis austeníticos, especialmente do tipo AISI 316L, aliam estas propriedades com a possibilidade de fabricação a um baixo custo. No entanto, são susceptíveis à corrosão nos fluidos fisiológicos e seus produtos de corrosão podem causar reações alérgicas ou infecciosas nos tecidos vizinhos ao implante. No presente trabalho, a aplicação de revestimentos obtidos por processos de deposição física de vapor (PVD) sobre um aço inoxidável austenítico do tipo AISI 316L foi realizada a fim de aumentar sua resistência à corrosão e biocompatibilidade. Os filmes depositados foram de nitreto de titânio (TiN), carbonitreto de titânio (TiCN) e de carbono tipo diamante (DLC). Estes materiais têm alta dureza e resistência ao desgaste, além de biocompatibilidade intrínseca, características altamente desejáveis para aplicações biomédicas. A caracterização do comportamento eletroquímico do aço com os três tipos de revestimentos mostrou que a presença de defeitos na superfície das camadas depositadas exerce uma influência negativa sobre a resistência à corrosão do substrato. A presença dos defeitos foi evidenciada por microscopia eletrônica de varredura. Foi proposto um mecanismo, com base nos dados obtidos por espectroscopia de impedância eletroquímica, para explicar a evolução do comportamento eletroquímico do aço com os diferentes revestimentos ao longo do tempo de imersão. Foram também empregados dois tratamentos de passivação da superfície do aço em soluções de ácido sulfúrico e ácido nítrico, a fim de aumentar a resistência à corrosão do substrato. Os resultados indicaram que os tratamentos utilizados não foram eficientes para melhorar esta característica, mas podem ser modificados visando um desempenho superior. As propriedades eletrônicas dos filmes passivos formados, tanto sobre o aço sem tratamento de passivação como sobre o aço passivado, foram estudadas utilizando a abordagem de Mott-Schottky. Os filmes apresentaram um caráter duplex, mostrando comportamento de um semicondutor altamente dopado acima e abaixo do potencial de banda plana. A concentração de dopantes no filme passivo foi associada à resistência à corrosão do material. Os três revestimentos PVD investigados apresentaram comportamento não citotóxico. Considerando a diminuição do coeficiente de atrito do aço 316L, os revestimentos de TiCN e o DLC foram os mais eficientes. Estas características, aliadas ao fator custo, sugerem que a aplicação comercial destes materiais sobre implantes ortopédicos pode ser viável. No entanto, a resistência à corrosão, conforme a avaliação realizada no presente estudo, não foi adequada quando comparada ao desempenho do aço sem nenhum tipo de revestimento. Ao final do texto, são apresentadas algumas sugestões a fim de conseguir um desempenho superior para a capacidade protetora dos revestimentos PVD. / Metallic biomaterials must present a combination of properties such as corrosion resistance, biocompatibility and mechanical resistance. Austenitic stainless steels, especially AISI 316L combine these properties with the easy of fabrication at low cost. However, they are prone to corrosion in physiological solutions. Furthermore, their corrosion products may lead to infectious ou allergenic reactions in the tissues around the implant device. In the present work, coatings produced by physical vapour deposition (PVD) methods have been applied on the surface of a 316L stainless steel to increase its corrosion resistance and biocompatibility. Three thin films were tested: titanium nitride (TiN), titanium carbonitride (TiCN) and diamond-like carbon (DLC). These materials present high hardness, wear resistance and intrinsic biocompatibility that are key features when considering biomedical applications. The characterization of the electrochemical behavior of the stainless steel coated with the three different films showed that the presence of surface defects are deleterious to the corrosion resistance of the substrate. These defects were observed using scanning electron microscopy. The evolution of the electrochemical behavior of the coated steel was explained through a mechanism based on the experimental results obtained using electrochemical impedance spectroscopy. Two different passivation treatments were carried out on the stainless steel surface, either in sulfuric or nitric acid solutions, to increase its corrosion resistance. The results suggested que these treatments were not efficient, but may be modified to improve its performance. The electronic properties of the passive films of the non-passivated and passivated stainless steel were studied using the Mott-Schottky approach. The films presented a duplex character. Below the flatband potential the behavior is typical of a highly doped type-p semiconductor. Above the flatband potential is typical of a highly doped type-n semiconductor. The doping concentration in the passive film was determined and associated with the corrosion resistance of the substrate. All PVD coatings investigated showed non-cytotoxic behavior. DLC and TiCN coatings decreased the friction coefficient of the stainless steel substrate. These properties allied with the stainless steel low cost recommend their commercial use for implants materials purposes. Nevertheless the corrosion resistance presented by the coated-steel was inferior to that of the bare steel and should be improved. At the end of the present text, some suggestions are proposed in order to improve the corrosion protection performance of the PVD coatings.

316L

316L

biomateriais

biomaterials

corrosao

corrosion

DLC

DLC

PVD

PVD

TiCN

TiCN

TiN

TiN

The synthesis and characterization of mixed-organic-cations tin halide perovskites for enhanced photovoltaic cell application

Ndzimandze, Samkeliso Sanele

January 2018

Magister Scientiae - MSc / In this research, novel hybrid perovskite materials were synthesized, characterized and applied in photovoltaic cells (PVCs) to enhance the performance of PVCs. Mixed-organic-cations tin halide perovskites (MOCTPs) were successfully synthesized using sol-gel method. These MOCTPs include guanidinium dimethylammonium tin iodide ([GA][(CH3)2NH2]SnI3) and guanidinium ethylmmonium tin iodide ([GA][CH3CH2NH3]SnI3). The MOCTPs were studied in comparison to their single-organic-cation tin perovskites (SOCTPs), which include guanidinium tin iodide (GASnI3), ethylammonium tin iodide ([CH3CH2NH3]SnI3) and dimethylammonium tin iodide [(CH3)2NH2]SnI3. High Resolution Scanning Electron Microscopy (HR SEM) of the five perovskite materials showed good crystallinity and tetragonal and hexagonal cubic shapes, characteristic of perovskites. These shapes were also confirmed from High Resolution Transmission Electron Microscopy (HR TEM), and the internal structure of the perovskites gave similar zone axes (ZAs) with those obtained from X-ray Diffraction (XRD). XRD showed tetragonal lattice shape for these perovskite materials. Fourier Transform Infrared (FTIR) demonstrated similar functional groups for both the SOCTPs and MOCTPs. FTIR bands that were observed are; N-H, C-H sp3, C-H aldehyde, N-H bend, C-N sp3 and N-H wag. From the 13C Nuclear Magnetic Resonance (NMR) results, the carbon atom of guanidinium iodide precursor shifts from downfield to upfield position, e.g. from 110.57 ppm to 38.49 ppm in GASnI3 SOCTP. This confirms a shift upfield of the carbon atom in guanidinium iodide precursor as it bonded to Sn metal in the perovskite chemical structure. Similar behavior was also observed for the NMR spectra of [GA][CH3CH2NH3]SnI3 MOCTP, where C-2 and C-3 atoms of ethylammonium iodide precursor shifted upfield from 37.03 ppm to 15.69 ppm and 16.06 ppm to 14.39 ppm respectively.

Dimethylammonium tin iodide

Electrochemical

Energy band-gap

Optical

Ethylammonium tin iodide

Capteurs de gaz sélectifs à base de matériaux hybrides organooxoétain et d'oxyde d'étain / Selective gas sensors based on tin dioxide and hybrid oxohydroxoorganotin materials

Lee, Szu-Hsuan

20 March 2019

L'objectif de cette recherche est d’explorer de nouvelles voies dans le domaine de la détection de gaz en ajustant finement la nature chimique, la texture et la morphologie de la couche active pour concevoir de nouveaux capteurs de gaz sélectifs. Ainsi, l’obtention de matériau présentant une haute sélectivité vis-à-vis des gaz constitue un enjeu majeur dans le domaine des capteurs de gaz. Notre approche est basée sur la conception de précurseurs moléculaires uniques - les alcynylorganoétains - qui contiennent toutes les fonctionnalités requises pour obtenir des matériaux hybrides stables par le procédé sol-gel, ces matériaux permettant une détection sélective des gaz nocifs / toxiques. Puis, les propriétés de détection de gaz de ces matériaux ont été comparées à celles de nanoparticules de dioxyde d'étain (SnO2) synthétisées à pression autogène. Une série de matériaux fonctionnels à base d'organooxoétains a été déposé sous forme de films minces films par le procédé d’enduction centrifuge puis ces films ont été caractérisés par des mesures de XRD, FT-IR, RAMAN, AFM, SEM, TEM, sorption d’azote et TGA-DTA. Les études de détection de gaz montrent que l'un des oxydes d'organoétain hybride présente une réponse sélective de détection de gaz tels que le CO, H2, l'éthanol, l'acétone et le NO2, tandis que les nanoparticules SnO2 conduisent à une détection non sélective des m^mes gaz dans les mêmes conditions. Ainsi, la meilleure sélectivité vis-à-vis du CO (à 100 et 200 ppm), de H2 (à 100, 200 et 400 ppm) et de NO2 (à 1, 2, 4 et 8 ppm) a été obtenue à 100 ° C pour le matériau hybride organostannique tandis que ce matériau ne conduisait à aucune réponse avec l’éthanol et l’acétone. Par ailleurs, les films de SnO2 nanoparticulaire sont sensibles à tous les gaz testés à de faibles concentrations (CO: 10 ~ 100 ppm, NO2: 0,5 à 4 ppm, H2: 100 à 800 ppm, acétone: 25 à 200 ppm, éthanol : 10 ~ 100 ppm) sur une plage de température comprise entre 200 et 400 °C. En outre, la sélectivité des matériaux SnO2 vis-à-vis de NO2 (entre 0,5 à 4 ppm) peut être optimisée en contrôlent bien la température de détection. Enfin, les matériaux à base d’organoétains et de dioxyde d’étain présentent une capacité de détection de gaz très élevée à de faibles concentrations en gaz. Ces résultats ont permis de développer une classe de matériaux entièrement nouvelle pour la détection sélective de gaz ainsi offrent la possibilité d'intégrer une fonctionnalité organique dans les oxydes métalliques capables de détecter les gaz. / The ultimate objective of this research is to draw new prospects in the gas sensing field by finely tuning the chemical nature, the texture and the morphology of the active layer to develop new type selective gas sensors. High gas selectivity has been a challenging issue during the past decades in the gas sensing area. Our approach is based on the design of molecular single precursors – alkynylorganotins which contain suitable functionalities required to obtain stable hybrid materials by the sol-gel method exhibiting selective gas detection towards harmful/toxic gases. Their gas sensing properties have been compared with those of tin dioxide (SnO2) nanoparticles synthesized by the hydrothermal route. A series of functional organooxotin-based materials have been processed as films by the spin or drop coating method and characterized by XRD, FT-IR, RAMAN, AFM, SEM, TEM, N2 sorption and TGA-DTA measurements. Gas sensing studies show that one of the hybrid organotin oxides exhibits an outstanding selective gas sensing response towards various gases, such as CO, H2, ethanol, acetone and NO2 whereas SnO2 nanoparticles present non-selective gas sensing ability under the same experimental condition. Thus, the best gas selectivity toward CO (at 100 and 200 ppm), H2 (at 100, 200 and 400 ppm) and NO2 (at 1, 2, 4 and 8 ppm) was achieved at 100 °C for the hybrid organooxotin-based film, however, it showed no response to ethanol/acetone at the same working temperature. On the other hand, the nanoparticulate SnO2 films prepared are sensitive to all the gases tested at low concentrations (CO: 10~100 ppm; NO2: 0.5~4 ppm; H2: 100~800 ppm; acetone: 25~200 ppm; ethanol: 10~100 ppm) in an operating temperature range from 200 to 400 °C. Moreover, the selectivity of SnO2 materials towards NO2 (between 0.5 ~ 4 ppm) can be optimized by well-manipulating the sensing temperatures. Finally, both organooxotin-based and tin oxide-based materials display superior gas sensing ability at low gas concentrations which opens a fully new class of gas sensing materials as well as a new possibility to integrate organic functionality in gas sensing metal oxides.

Sélectivité

Matériaux hybrides

Oxyde d'étain

Capteurs de gaz

Selectivity

Tin-based hybrid materials

Tin dioxide

Gas sensors

Abscheidung funktioneller Schichten mittels Plasmatronzerstäubung

Kupfer, Hartmut, Ackermann, Eckehard, Hecht, Günther

28 April 2010

Zinn- und Zinnlegierungsschichten wurden mittels einer Magnetronquelle auf CuSn6- Substrate aufgebracht. Durch Wahl geeigneter Legierungspartner (Al. Ti), die galvanisch nicht abscheidbar sind, konnten Schichtwerkstoffe mit neuen Eigenschaften hergestellt und hinsichtlich einer Eignung als Kontaktveredelung geprüft werden. Verantwortlich dafür ist eine Umwandlung der grobkristallinen, durch säulenförmige Kristallite geprägten in eine feinkristalline dichte, zur Oberfläche parallel orientierte Struktur.

Magnetronzerstäubung

Zinnlegierungen

contact material

sputtering

tin

tin alloys

ddc:530

Kontaktwerkstoff

Zinn

The classification and interpretation of tin smelting remains from South West England : a study of the microstructure and chemical composition of tin smelting slags from Devon and Cornwall, and the effect of technological developments upon the character of slags

Malham, Albertine

January 2010

Artefacts relating to tin smelting from tin mills or 'blowing houses' in Devon and Cornwall, plus material from smelting sites that cover a range of dates from the Bronze Age through to the 19th Century, were examined: these include metallic tin, furnace linings, ore samples and slag. Analysis of tin slags from over forty sites was carried out, to determine microstructure and chemical composition. Techniques employed included optical and scanning electron microscopy, X-ray fluorescence and ICP mass spectrometry. Analysis indicates that slag appearance and composition are heavily influenced by local geology. Composition, particularly iron content, is shown to have a strong effect on slag melting point and viscosity, and the implications for the purity of metal produced are discussed. Bringing together the evidence provided by slag chemistry, documentary sources and smelting remains in the archaeological record, changes in tin smelting technology through time, and the consequences thereof, are considered.

930