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Process Window Challenges in Advanced Manufacturing: New Materials and Integration SolutionsFox, Robert, Augur, Rod, Child, Craig, Zaleski, Mark 22 July 2016 (has links) (PDF)
With the continued progression of Moore’s law into the sub-14nm technology nodes, interconnect RC and power dissipation scaling play an increasingly important role in overall product performance. As critical dimensions in the mainstream Cu/ULK interconnect system shrink below 30nm, corresponding increases in relative process variation and decreases in overall process window mandate increasingly complex integrated solutions. Traditional metallization processes, e.g. PVD barrier and seed layers, no longer scale for all layout configurations as they reach physical and geometric limitations. Interactions between design, OPC, and patterning also play more and more critical roles with respect to reliability and yield in volume manufacturing; stated simply, scaling is no longer “business as usual”. Restricted design layouts, prescriptive design rules, novel materials, and holistic integration solutions each therefore become necessary to maximize available process windows, thus enabling new generations of cost-competitive products in the marketplace.
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Synthesis and Investigations of type I and II clathrates of Group 14Blosser, Michael 01 January 2013 (has links)
Clathrates are a class of new materials that have an open-framework structure that allows guest atoms or molecules to be enclosed inside of their polyhedral framework. Varying the number, weight, and size of the guest species in a particular framework allows one to alter the physical properties of the clathrate. This relationship enables one to further the fundamental understanding of the physics and chemistry of the clathrate structure and use this knowledge to "tune" certain properties. This "tunability" of inorganic clathrates is of great interest as it allows one to optimize their physical properties; making them promising candidates for a range of applications such as thermoelectric, optoelectronic, and superconductivity.
In this study, new synthesis methods of type I and II clathrates of group 14 are introduced, along with two new compositions of type I clathrates. A new synthesis method used to produce single crystal and microcrystalline Na8Si46 and Na24Si136 clathrates by the spark plasma sintering technique is introduced. Microcrystalline type I Na8Si46 and type II Na24Si136 are also selectively synthesized with no phase impurity of the other type using the low temperature ionic liquid method. In addition, the synthesis of microcrystalline Na8Ge3Si38 and single crystal Ba2Cs6Ga8Sn38 type I clathrates are presented for the first time.
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Structure Property and Prediction of Novel Materials using Advanced Molecular Dynamics Techniques: Novel Carbons, Germaniums and High-Performance ThermoelectricsSelli, Daniele 06 August 2014 (has links) (PDF)
By means of advanced molecular dynamic techniques, we predict the stability of novel materials based on carbon, germanium and PbSe. This topological solutions have been studied and characterised at a DFT/DFTB level of theory and interesting optical, mechanical, electronic and heat transport properties have been pointed out.
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Structure Property and Prediction of Novel Materials using Advanced Molecular Dynamics Techniques: Novel Carbons, Germaniums and High-Performance ThermoelectricsSelli, Daniele 26 March 2014 (has links)
By means of advanced molecular dynamic techniques, we predict the stability of novel materials based on carbon, germanium and PbSe. This topological solutions have been studied and characterised at a DFT/DFTB level of theory and interesting optical, mechanical, electronic and heat transport properties have been pointed out.
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Modular Sound Absorbing Unit : A system solution for implementation of noise abatement appliance in indoor environmentsOdevik, William, Wästersved Nyberg, Viktor January 2020 (has links)
There is a rising concern about the effects of noise on human health. The noise from our technologies and comforts that evokes a negative physiological response as a response, effects like cardiovascular disease, cognitive and hearing impairments are all examples of critical health results stemming from prolonged noise exposure (WHO, 2004 & 2018). A reaction to the insight of the effects of noise pollution is directives and policies to fight noise pollution, both at a European union level but also member state level (EU, 2002). The applied Swedish policy is enforced by the Swedish work environment authority which has given the following provision for indoor environments and workplace design (AFS 2009:2) which states “4 § Work should be planned, conducted and be followed up so that noise exposure is reduced through eliminating noise from its source or is reduced as much as possible. Consideration should also be taken into the technological advancements and the possibilities to reduce noise.”. This is where this master thesis project comes in to develop a modular sound absorbing unit that could help in the fight against noise pollution and reduce the negative effects of prolonged noise exposure. The master thesis is performed as a part of our final master’s degree course in the program- me of industrial design engineering at the Luleå University of Technology. The company Sontech International AB served as client and collaborator for the master thesis. The objective for the project was to develop a modular sound absorbing unit that uses Sontech’s unique sound absorbing materials to break into a new market, diverging from their previous focus on industrial applications. The project was based in the product design specification developed in the inspiration phase of our project, stemming from the data gathered in needfinding and current state analysis, in conjunction with Sontech. The product design specification was split into three segments of need, function and design which was used in the remaining phases of ideation and implementation. From there the ideation phase consisted of different types of brainstorming methods and explorative prototyping to cre- ate a large sum of ideas to later be analysed through a design space evaluation process which resulted in five distinct concepts. The ideation phase was concluded in a selection of the final concepts to be brought into the implementation phase. The implementation phase entailed refinement of the concepts through testing and detail design. The final design concluded in a modular sound absorbing system called Unison which consist of two modes of thinking, vertical aligned units called Acustibrick for building sound absorbing walls. The other is horizontally aligned units called Acustitile made for creating sound absorbing & deflecting roofs. For each of unit there is the option two pick two types of material, acustimet which is an aluminium sheet with micro perforations which gives it its sound absorbing properties. The second material is acustiboard which is a cardboard sheet made of paper honeycomb and two thin outer layers of paper, this outer layer is perforated to give the material its sound absorbing properties. The units are constructed with stamped holes, called interface, which are aligned to allow mounting on different objects depending on the user’s choice. These objects, called the architecture, can be rods, pipes, wires, ropes etc. depending on how the user chooses to implement the system in their environment. This modular system will allow the user to construct their own arrays of units, with their own resources, to shape and better their noise environment. / Det finns en ökande oro över effekterna av buller på människors hälsa. Bullret från vår teknik och bekvämligheter som framkallar en negativ fysiologisk respons som svar, effekter som hjärt-kärlsjukdom, kognitiva och hörselnedsättningar är alla exempel på kritiska hälsoresultat som härrör från långvarig bullerexponering (WHO, 2004 & 2018). En reaktion på insikten om effekterna av bullerföroreningar är direktiv och politik för att bekämpa bullerföroreningar, både på EU-nivå men också på medlemsstatsnivå (EU, 2002). Den tillämpade svenska policyn upprätthålls av Arbetsmiljöverket som har gett följande bestämmelser för inomhusmiljöer och arbetsplatsdesign (AFS 2009:2) där det står “4 § arbete bör planeras, genomföras och följas upp så att bullerexponeringen reduceras genom att eliminera buller från dess källa eller minskas så mycket som möjligt. Hänsyn bör också tas till de tekniska framstegen och möjligheterna att minska bullret. “. Det är här detta examensarbete kommer in för att utveckla en modulär ljudabsorberande enhet som kan hjälpa till i kampen mot buller och minska de negativa effekterna av långvarig bullerexponering. Examensarbetet utförs som en del av vår slutgiltiga magisterkurs i programmet industriell design Engineering vid Luleå tekniska universitet. Företaget Sontech International AB verkade som klient och samarbetspartner för examensarbetet. Målet för projektet var att utveckla en modulär ljudabsorberande enhet som använder Sontechs unika ljudabsorberande material för att bryta sig in i en ny marknad och avvika från deras tidigare fokus på industriella tillämpningar. Projektet baserades på produktdesign specifikationen som utvecklades i inspirations fasen av vårt projekt, som härrör från de data som samlats in i needfinding och current state analys, tillsammans med Sontech. Produktdesign specifikationen delades upp i tre segment av behov, funktion och design som användes i de återstående faserna av ideation och implementation. Ideationsfasen bestod av olika typer av brainstorming-metoder och utforskande prototyper för att skapa en stor summa idéer som senare kunde analyseras genom en utvärderingsprocess som resulterade i fem distinkta koncept. Ideationfasen avslutades i ett urval av de slutgiltiga koncepten som skulle föras in i implementation fasen. Implementeringsfasen innebar förfining av koncepten genom testning och detaljdesign. Den slutliga utformningen slutade med ett modulärt ljudabsorberande system som kallas unison som består av två sätt att tänka, vertikala justerade enheter kallas Acustibrick för att bygga ljudabsorberande väggar. Den andra är horisontellt anpassade enheter kallas Acustitile gjort för att skapa ljudabsorberande & reflekterande tak. För varje enhet finns alternativet att plocka två typer av material, acustimet som är en aluminiumplåt med mikroperforeringar som ger den dess ljudabsorberande egenskaper. Det andra materialet är acustiboard som är en pappskiva gjord av en kärna av papper i ett honeycomb mönster och två tunna yttre lager av papper, detta yttre skikt är perforerad för att ge materialet dess ljudabsorberande egenskaper. Enheterna är konstruerade med stämplade hål, kallas Interface, som är justerade för att tillåta montering på olika objekt beroende på användarnas val. Dessa objekt, som kallas arkitektur, kan vara stavar, rör, ledningar, rep etc. beroende på hur användaren väljer att implementera systemet i sin omgivning. Detta modulära system gör det möjligt för användaren att konstruera sina egna matriser av enheter, med sina egna resurser, för att forma och förbättra sin bullermiljö.
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Novel materials for VOC analysisMalan, Mareta 12 1900 (has links)
Thesis (MSc)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: The need to analyse and detect volatile organic compounds (VOCs) at trace levels has led to the
development of specialized sample preparation techniques. The requirement for trace analysis of
VOCs stems from the negative effects they have on the environmental and human health. Methods
for the analysis of non-polar VOCs commonly found as trace contaminants in water and analysis of
more polar oxygenated compounds commonly found in zero-VOC water-based paints were
developed. Solid phase micro extraction (SPME) was employed and extraction of the majority of
the target analytes could be achieved at levels below 0.3 μg.l-1. In an attempt to further improve the
detection of these two target analyte groups, novel materials based on poly(dimethyl siloxane)
(PDMS) were investigated as possible extraction phases for VOCs, with the focus specifically on
the analysis of the polar analytes in paint. Conventional free radical polymerization was used to
synthesize poly(methyl methacrylate-graft-poly(dimethyl siloxane) (PMMA-g-PDMS),
poly(methacrylic acid)-graft-poly(dimethyl siloxane) (PMAA-g-PDMS), polystyrene-graftpoly(
dimethyl siloxane) (PSty-g-PDMS) and poly(butyl acrylate)-graft–poly(dimethyl siloxane)
(PBA-g-PDMS). These polymers have a copolymer functionality which presents a series of
different polarities. The MMA-g-PDMS and MAA-g-PDMS as well as the homopolymers were
electrospun into nanofibers. The low glass transition temperature and molecular weight of the PBAg-
PDMS meant that this polymer could not be electrospun. Scanning electron microscopy (SEM)
was used to study the fiber morphology of the electrospun fibers and the non-beaded fibers were
further investigated. Polyacrylonitrile-graft-poly(dimethyl siloxane) (PAN-g-PDMS) previously synthesized and electrospun by another member of the group were also investigated for use as
possible extraction material in volatile analysis. The thermal stability of the nanofibers at 200°C
was studied using thermal gravimetric analysis (TGA). This property is important since after the
target analytes are extracted using the nanofibers, elevated temperatures are used to thermally
desorp the volatile analytes from the extraction materials prior to GC analysis. The PAN-g-PDMS,
MMA-g-PDMS and PMMA showed no significant weight loss during thermal evaluation, however,
it was observed that the PMMA and PMMA-g-PDMS nanofibers looses their nanostructure and that
the PAN-g-PDMS nanofibers changes colour from white to yellow to rust brown. The polymers
based on MAA showed weight losses of more than 10% after one hour of exposure to the elevated
temperatures, but the nanostructure remained intact. The PAN-g-PDMS, PMAA-g-PDMS and
PMAA nanofibers were evaluated as possible extraction materials for VOC analysis. The
nanofibers were evaluated using a similar approach to that of stir bar sorptive extraction (SBSE).
Headspace sorptive extraction (HSSE) using a commercially available PDMS stir bar and the novel
materials were used to evaluate the extraction efficiency of the different materials. The optimized extraction method developed using SPME were employed for the extraction using the nanofibers
and PDMS stir bar. It was noted that the nanofibers lose their extraction capabilities during the first
extraction/desorption cycle possibly due to thermal degradation therefore each of the materials can
only be used in a single extraction. The majority of the non-polar analytes were extracted using the
nanofibers at levels of 500 μg.l-1, however it was noted that the commercially available SPME
extraction materials and the PDMS stir bar had superior extraction efficiencies for the specific
target analytes. In the evaluation of the nanofibers for extraction of the more polar oxygenated
analytes it was noted that 2-Ethylhexylacrylate was the only analyte to be extracted by all of the
materials. The PAN-g-PDMS extracted three of the four analytes at levels of 100 μg.l-1. At lower
analyte concentrations of 10 μg.l-1 only two of the four acrylate compounds were detected using the
PAN-g-PDMS nanofibers. Ethyl acrylate was not extracted by any of the novel materials, whereas
in SPME using the CAR/PDMS fiber, the LOD was determined to be below 1 μg.l-1. Although
these materials were not superior to the commercially available phases, this is only the case for the
specific target analytes analyzed. / AFRIKAANSE OPSOMMING: Die behoefte vir die analiese van vlugtige organiese verbindings (VOS) op spoorvlak, het gelei tot
die ontwikkeling van gespesialiseerde monster voorbereidingstegnieke. Die vereiste vir die spoor
analiese van die VOS het ontstaan uit die negatiewe uitwerking wat hierdie stowwe het op die
omgewing en menslike gesondheid. Metodes vir die analiese van nie-polêre VOS wat algemeen
voorkom as spoorkontaminante in water en polêre suurstofryke verbindings wat algemeen voorkom
in nul-VOS water-gebaseerde verf was ontwikkel. Soliede fase mikro-ekstraksie (SFME) was
gebruik, en die ekstraksie van die meerderheid van die teikenstowwe kon gedoen word op vlakke
laer as 0,3 μg.l-1. In 'n poging om die opsporing van hierdie twee teiken analietgroepe verder te verbeter, is nuwe materiale gebaseer op polidimetielsiloksaan (PDMS), ondersoek as moontlik
ekstraksiefases vir VOS, met die fokus spesifiek op die analiese van die polêre stowwe in verf. ’n
Konvensionele vrye radikaal polimerisasieproses was gebruik om poli (metiel- metakrilaat)-entpoli(
dimetielsiloksaan) (PMMA-g-PDMS), poli(metakrilaatsuur)-ent–poli (dimetielsiloksaan)
(PMAA-g-PDMS), polistireen-ent-poli(dimetielsiloksaan) (PSty-g-PDMS) en poli(butielakrilaat)-
ent-poli(dimetielsiloksaan) (PBA-g-PDMS) te sintetiseer. Hierdie ko-polimere het 'n kopolimeer
funksionaliteit wat 'n reeks van verskillende polariteite bied. Die MMA-g-PDMS en MAA-g-PDMS
sowel as die homopolimere was ge-elektrospin in orde om nanovesels te vorm. Die lae
glasoorgangstemperatuur en molekulêre gewig van die PBA-g-PDMS het beteken dat hierdie
polimeer nie elektrospin kon word nie. Skandeerelektronmikroskopie (SEM) was gebruik om die
veselmorfologie van die ge-elektrospinde vesels te bestudeer en die nanovesels wat ’n eweredige
oppervlak gehad het, was verder ondersoek. Poliakrilonitriel-ent-poli(dimetielsiloksaan) (PAN-g-
PDMS) wat voorheen gesintetiseer en ge-elektrospin was deur 'n ander lid van die groep is ook
ondersoek vir gebruik as moontlik ekstraksiemateriaal vir die analiese van vlugtige stowwe. Die
termiese stabiliteit van die nanovesels was by 200°C bestudeer met behulp van ‘n termiese
gravimetriese analiese (TGA) instrument. Hierdie eienskap is belangrik, aangesien die
teikenstowwe by hoë temperature van die nanovesels gedesorbeer word voor die GC-analiese. Die
PAN-g-PDMS, MMA-g-PDMS en PMMA het geen beduidende gewigsverlies tydens termiese
evaluering gehad nie, alhoewel dit egter waargeneem was dat die PMMA en PMMA-g-PDMS
nanovesels hulle nanostruktuur verloor en dat die PAN-g-PDMS nanovesels se kleur verander van
wit na geel na roesbruin gedurende die termiese analiese. Die polimere wat gebaseer was op MAA
het ’n gewigs-verlies van meer as 10% getoon na 'n uur van blootstelling aan die verhoogde
temperature, maar die nanostruktuur het ongeskonde gebly. Die PAN-g-PDMS, PMAA-g-PDMS en
PMAA nanovesels was geëvalueer as moontlike ekstraksiemateriale vir VOS-analiese. Die
nanovesels was geëvalueer met 'n soortgelyke benadering tot dié van “stir bar“ sorpsie ekstraksie (SBSE). Bo-ruimte sorpsie ekstrasie is gebruik om die ekstraksie-doeltreffendheid van die
verskillende materiale (kommersiële PDMS en nanovesels) te evalueer. Die geoptimaliseerde
ekstraksiemetode ontwikkel in SFME was gebruik vir die ekstraksie van die VOS met die
nanovesels en die PDMS “stir bar“. Dit was waargeneem dat die nanovesels hul ekstraksievermoë
verloor tydens die eerste ekstraksie/desorpsie siklus, moontlik as gevolg van termiese degradasie
dus, kon die materiale slegs ‘n enkele maal gebruik word vir die ekstraksie. Die meerderheid van
die nie-polêre stowwe was ge-ëkstraeer deur gebruik te maak van die nanovesels op vlakke van 500
μg.l -1, maar die kommersieel beskikbare SFME ekstraksie materiale en die PDMS “stir bar“ se
ekstraksie-doeltreffendheid vir die spesifieke stowwe was beter. In die evaluering van die
nanovesels vir die ekstraksie van die meer polêre suurstofryke stowwe was daar waargeneem dat 2-
etielheksielakrilaat die enigste analiet was wat ge-ëkstraeer was deur al die materiale. Die PAN-g-
PDMS kon drie van die vier polêre stowwe op vlakke van 100 μg.l-1 opspoor. By laer
analietkonsentrasies van 10 μg.l-1 kon slegs twee van die vier akrilaat verbindings opgespoor word
deur gebruik te maak van hierdie nanovesels. Etielakrilaat was nie ge-ëkstraeer deur enige van die
nuwe materiale nie, terwyl in SFME met die gebruik van die CAR/ PDMS vesel, die analiet op
vlakke onder 1 μg.l-1 opgespoor kon word. Alhoewel hierdie nuwe materiale nie beter is as die
kommersieel beskikbare ekstraksiemateriale nie is dit net die geval vir die spesifieke teiken
analietgroepe wat ondersoek was in hierdie studie.
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Theoretical Studies Of Nanostructure Formation And Transport On SurfacesAminpour, Maral 01 January 2013 (has links)
This dissertation undertakes theoretical and computational research to characterize and understand in detail atomic configurations and electronic structural properties of surfaces and interfaces at the nano-scale, with particular emphasis on identifying the factors that control atomic-scale diffusion and transport properties. The overarching goal is to outline, with examples, a predictive modeling procedure of stable structures of novel materials that, on the one hand, facilitates a better understanding of experimental results, and on the other hand, provide guidelines for future experimental work. The results of this dissertation are useful in future miniaturization of electronic devices, predicting and engineering functional novel nanostructures. A variety of theoretical and computational tools with different degrees of accuracy is used to study problems in different time and length scales. Interactions between the atoms are derived using both ab-initio methods based on Density Functional Theory (DFT), as well as semiempirical approaches such as those embodied in the Embedded Atom Method (EAM), depending on the scale of the problem at hand. The energetics for a variety of surface phenomena (adsorption, desorption, diffusion, and reactions) are calculated using either DFT or EAM, as feasible. For simulating dynamic processes such as diffusion of adatoms on surfaces with dislocations the Molecular Dynamics (MD) method is applied. To calculate vibrational mode frequencies, the infinitesimal displacement method is employed. The combination of non-equilibrium Green’s function (NEGF) and DFT is used to calculate electronic transport properties of molecular devices as well as interfaces and junctions.
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Investigation Of Transition Metal Oxides Of Perovskite, Pyrochlore And Rutile Structures Towards Realization Of Novel MaterialsMani, Rohini 07 1900 (has links)
Materials chemistry is essentially concerned with the design/synthesis of new solids endowed with functional properties that could be of relevance to today’s materials technology. Among the large variety of solid materials that attract attention, metal oxides continue to contribute significantly to current materials chemistry. A wide variety of oxide materials (based on rocksalt, spinel, corundum, perovskite, garnet, pyrochlore and other structures) and their properties have been investigated over the years. Most of these oxides are derived from the transition metals.
Transition metal oxides with structures derived from metal-oxygen (MO6) octahedra, in particular, display an array of exotic properties with potential or proven technological application. While it is traditionally believed that the partially filled d shell (dn : 0 < n < 10) of the transition metal atoms plays a crucial role in deciding the electronic properties, the significance of d0 metal atoms for the properties (and structure) of transition metal oxides is not fully recognized. Magnetism (SrRuO3, Fe3O4), metallicity (ReO3, LaNiO3), colossal magnetoresistance (La1-xCaxMnO3) and superconductivity (La2xSrxCuO4, Sr2RuO4) are some of the properties that can be traced to the presence of partially filled d shell, while properties like ferroelectricity (BaTiO3), piezoelectricity (PbZr1-xTixO3) and nonlinear optical response (LiNbO3) could be traced to the presence of transition metals (TiIV, ZrIV, NbV) with d0 electronic configuration. The empty d orbitals on the metal atoms constitute the low lying unoccupied states (LUMO) that mix with the highest occupied states (HOMO) of the ligand atoms (oxygen) through special chemical bonding effects (second order Jahn-Teller effect, SOJT). This mixing results, among others, in out-of-centre distortion(s) of the MO6 octahedra and this distortion is at the heart of several properties mentioned above.
Among the transition metal oxide structures based on MO6 octahedra, three structures are noteworthy: the perovskite, the pyrochlore and the rutile. The AMO3 perovskite structure consists of a three-dimensional framework of corner sharing MO6 octahedra in which the A cation occupies the dodecahedral site surrounded by twelve oxide ions. The perovskite structure can accommodate a large variety of substitutions at both the A and the M sites as well as vacancies at the A/O sites, giving a large number of derivatives. Several variants of the perovskite structure are also known, for instance, the layered perovskites and ordered perovskites. Many nonperovskite structures are also known for the composition AMO3 : hexagonal YMnO3 is an alternative structure for AMO3 composition where manganese exists as MnO5 trigonal bipyramids. The A2M2O7 pyrochlore structure is also based on a corner-connected network of MO6 octahedra which interpenetrates an A2O network. The rutile (TiO2) is a well-known structure consisting of chains of edge-sharing MO6 octahedra, which are connected through corners to adjacent chains.
A large number of oxide materials based on the above three structure types have been reported : for example, perovskite [Ba3ZnTa2O9 (microwave telecommunication ceramic), Pb3MgNb2O9 (relaxor ferroelectric), Bi4Ti3O12 (high temperature ferroelectric)], pyrochlore [Nd2Mo2O7 (metallic ferromagnet), AOs2O6 for A = K, Rb, Cs (superconductor)] and rutile [TiO2 (photocatalyst), CrO2 (metallic ferromagnet), VO2 (insulator-metal transition)]. Considering the current interest in oxide materials of these three structure types which continue to generate new variants and novel properties, we undertook the present research project to synthesize new derivatives of these structure types, and characterize their structures and relevant electronic properties. In doing so, we recognized that synthesis based on an understanding of the reactivity of the constituents and crystal chemistry of the expected products plays a crucial role in this effort. Accordingly, we tailored several new compositions of AMO3, A2M2O7 and MO2 stoichiometries and adopted appropriate methodologies for their synthesis. We have characterized the structures and properties of the solid products by means of state-of-the-art methods available to us.
There are two main approaches to the synthesis of nonmolecular inorganic solids: conventional ceramic route and chimie douce / soft chemistry routes. In the ceramic route, solid reactants are heated at elevated temperatures for long durations with intermittent mixing/grinding until the reaction is complete. Chimie douce routes, on the other hand, utilize gentle reactions such as dehydration, decomposition, intercalation, ion exchange, and so on to synthesize the desired phases. The ceramic route generally provides access to the thermodynamically controlled product(s), while chimie douce routes allow access to metastable phases (kinetically controlled product(s)). Disadvantages notwithstanding, the ceramic route has been the mainstay of materials chemistry and several important materials continue to be discovered / synthesized by this route. The choice of the synthetic route based on an understanding of the crystal chemical preferences and the reactivities of the constituents involved is often crucial to achieve the desired final products.
The present thesis is devoted to the synthesis and investigation of MO6 octahedra-based oxides belonging to the perovskite, pyrochlore and rutile structure types wherein we have explored alternate synthetic strategies (perovskite-based Ba3MM'2O9 telecommunication ceramics and a solution route for the synthesis of ruthenium-based pyrochlores) and probed structure-property relations of perovskite oxides (Ba3MM'M''O9 oxides for various M/M'/M'' atoms) as well as formation of new derivatives of layered Aurivillius phases. In addition, we have also synthesized new noncentrosymmetric oxides possessing the YMnO3 structure. Our investigation of rutile based oxides has resulted in the discovery of a new lead-free relaxor ferroelectric material, FeTiTaO6. Given that the lone pair PbII:6s2 plays a crucial role in the ferroelectric properties of Pb-based perovskite oxides, we have also investigated members of the Pb1-xLix/2Lax/2TiO3 system for their structure and dielectric response.
The present thesis describes the results of these investigations in eight chapters. Chapter 1 provides a general introduction to oxides of the perovskite, pyrochlore and rutile structures. In Chapter 2, we describe a new one-pot metathesis strategy for the synthesis of dielectric ceramics Ba3MM'2O9 (M = Mg, Ni, Zn; M' = Nb, Ta). Rietveld refinement of X-ray diffraction data shows near-complete ordering of M-site ions in many cases. The dielectric properties of the products synthesized are found to be in reasonable agreement with reported data. The synthesis of ordered materials at lower temperatures (~1100 °C) than that employed in the conventional ceramic route (~1500 °C) is a significant result of this work.
Chapter 3 presents a study of Ba3MIIMIVWO9 (MII = Ca, Zn; MIV = Ti, Zr) perovskite oxides for the purpose of synthesizing new dielectric ceramic materials and to gain understanding of the factors that stabilize 3C vs. 6H structures. In general, a 1:2-ordered 6H perovskite structure is stabilized at high temperatures (1300 °C) for all of the Ba3MIITiWO9 oxides investigated. An intermediate phase possessing a partially ordered 1:1 double perovskite (3C) structure with the cation distribution, Ba2(Zn2/3Ti1/3)(W2/3Ti1/3)O6, is obtained at 1200 °C for Ba3ZnTiWO9. A metastable perovskite, Ba3CaZrWO9, that adopts the 1:1 3C structure has also been synthesized by a low-temperature metathesis route. Besides yielding several new perovskite oxides that may be useful as dielectric ceramics, the investigation provides new insights into the complex interplay of crystal chemistry (tolerance factor) and chemical bonding (anion polarization and d0-induced distortion of metaloxygen octahedra) in the stabilization of 6H versus 3C perovskite structures for the Ba3MIIMIVWO9 series.
In Chapter 4, we describe the synthesis and investigation of the structure and dielectric properties of Ba3MIIITiMVO9 (MIII = Fe, Ga, Y, Lu; MV = Nb, Ta, Sb) perovskite oxides. The MV = Nb, Ta oxides adopt disordered/partially ordered 3C perovskite structures, where all the MIII/Ti/MV metal-oxygen octahedra are corner-connected. In contrast, the MV = Sb oxides show a distinct preference for the 6H structure, where SbV/TiIV metal-oxygen octahedra share a common face, forming (Sb,Ti)O9 dimers, that are corner-connected to the MIIIO6 octahedra. Investigation of dielectric properties of MIII = Y/Lu, MV = Nb/Ta oxides reveals a normal low loss dielectric behaviour with ε = 30 – 50 in the temperature range 50 – 350 °C. The MIII = Fe, MV = Nb/Ta members show a dielectric behaviour similar to relaxor ferroelectric materials.
Chapter 5 deals with a study of isomorphous substitution of several metal atoms in two Aurivillius structures, Bi5TiNbWO15 and Bi4Ti3O12, in an effort to probe structure-property correlations. These investigations have led to the synthesis of new derivatives, Bi4LnTiMWO15 (Ln, = La, Pr; M = Nb, Ta), as well as Bi4PbNb2WO15 and Bi3LaPbNb2WO15, that largely retain the Aurivillius intergrowth structure of the parent oxide Bi5TiNbWO15, but characteristically tend toward a centrosymmetric / tetragonal structure for the Ln-substituted derivatives. On the other hand, coupled substitution, 2TiIV Æ MV + FeIII in Bi4Ti3O12, yields new Aurivillius phases, Bi4Ti3-2xNbxFexO12 (x = 0.25, 0.50) and Bi4Ti3-2xTaxFexO12 (x = 0.25) that retain the orthorhombic noncentrosymmetric structure of the parent Bi4Ti3O12.
Chapter 6 describes the design and synthesis of a new series of noncentrosymmetric oxides, R3Mn1.5CuV0.5O9 (R = Y, Ho, Er, Tm, Yb, Lu) possessing the YMnO3 structure. Investigation of the Lu-Mn-Cu-V-O system revealed the existence of an isostructural solid solution series, Lu3Mn3-3xCu2xVxO9 for 0 < x ≤ 0.75. Magnetic and dielectric properties of the oxides are consistent with a random distribution of Mn3+, Cu2+ and V5+ atoms that preserves the noncentrosymmetric RMnO3 structure.
An exploratory investigation of the synthesis, structure and electronic properties of new ruthenium(IV) pyrochlore oxides and their manganese-substituted derivatives is presented in Chapter 7. The richness of the electronic properties of ruthenium-based metal oxides is affirmed by the results which revealed several novel electronic ground states : a metallic and Pauli paramagnetic state for BiPbRu2O6.5 that turns into a semiconducting ferromagnetic spin-glass state at 50 K for BiPbRuMnO6.5 ; a metallic state that likely shows a charge density wave (CDW) instability at 50-225 K for Bi1.50Zn0.50Ru2O6.75, that is suppressed by manganese substitution in Bi1.50Zn0.50Ru1.75Mn0.25O6.50, and a metallic ferromagnetic spin-glass-like state for Pb2Ru1.75Mn0.25O6.15.
We describe the investigation of the structure and dielectric properties of rutile-based MTiTaO6 (M = Al, Cr, Fe) in Chapter 8. All the oxides possess disordered rutile structure. FeTiTaO6 shows a strong relaxor ferroelectric effect, while CrTiTaO6 shows a weaker relaxor ferroelectric behaviour. This work is significant for two reasons: the new material is lead-free and it is based on the rutile structure, unlike the conventional relaxors which are mostly derived from the perovskite structure.
The work presented in the thesis is carried out by the candidate as a part of the Ph.D. training programme and most of it has been published in the literature. She hopes that the studies reported here will constitute a worthwhile contribution to materials chemistry in general.
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Process Window Challenges in Advanced Manufacturing: New Materials and Integration SolutionsFox, Robert, Augur, Rod, Child, Craig, Zaleski, Mark 22 July 2016 (has links)
With the continued progression of Moore’s law into the sub-14nm technology nodes, interconnect RC and power dissipation scaling play an increasingly important role in overall product performance. As critical dimensions in the mainstream Cu/ULK interconnect system shrink below 30nm, corresponding increases in relative process variation and decreases in overall process window mandate increasingly complex integrated solutions. Traditional metallization processes, e.g. PVD barrier and seed layers, no longer scale for all layout configurations as they reach physical and geometric limitations. Interactions between design, OPC, and patterning also play more and more critical roles with respect to reliability and yield in volume manufacturing; stated simply, scaling is no longer “business as usual”. Restricted design layouts, prescriptive design rules, novel materials, and holistic integration solutions each therefore become necessary to maximize available process windows, thus enabling new generations of cost-competitive products in the marketplace.
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Towards Efficient Novel Materials Discovery / Acceleration of High-throughput Calculations and Semantic Management of Big Data using OntologiesLenz-Himmer, Maja-Olivia 27 April 2022 (has links)
Die Entdeckung von neuen Materialien mit speziellen funktionalen Eigenschaften ist eins der wichtigsten Ziele in den Materialwissenschaften.
Das Screening des strukturellen und chemischen Phasenraums nach potentiellen neuen Materialkandidaten wird häufig durch den Einsatz von Hochdurchsatzmethoden erleichtert.
Schnelle und genaue Berechnungen sind eins der Hauptwerkzeuge solcher Screenings, deren erster Schritt oft Geometrierelaxationen sind.
In Teil I dieser Arbeit wird eine neue Methode der eingeschränkten Geometrierelaxation vorgestellt, welche die perfekte Symmetrie des Kristalls erhält, Resourcen spart sowie Relaxationen von metastabilen Phasen und Systemen mit lokalen Symmetrien und Verzerrungen erlaubt.
Neben der Verbesserung solcher Berechnungen um den Materialraum schneller zu durchleuchten ist auch eine bessere Nutzung vorhandener Daten ein wichtiger Pfeiler zur Beschleunigung der Entdeckung neuer Materialien.
Obwohl schon viele verschiedene Datenbanken für computerbasierte Materialdaten existieren ist die Nutzbarkeit abhängig von der Darstellung dieser Daten.
Hier untersuchen wir inwiefern semantische Technologien und Graphdarstellungen die Annotation von Daten verbessern können.
Verschiedene Ontologien und Wissensgraphen werden entwickelt anhand derer die semantische Darstellung von Kristallstrukturen, Materialeigenschaften sowie experimentellen Ergebenissen im Gebiet der heterogenen Katalyse ermöglicht werden.
Wir diskutieren, wie der Ansatz Ontologien und Wissensgraphen zu separieren, zusammenbricht wenn neues Wissen mit künstlicher Intelligenz involviert ist. Eine Zwischenebene wird als Lösung vorgeschlagen.
Die Ontologien bilden das Hintergrundwissen, welches als Grundlage von zukünftigen autonomen Agenten verwendet werden kann.
Zusammenfassend ist es noch ein langer Weg bis Materialdaten für Maschinen verständlich gemacht werden können, so das der direkte Nutzen semantischer Technologien nach aktuellem Stand in den Materialwissenschaften sehr limitiert ist. / The discovery of novel materials with specific functional properties is one of the highest goals in materials science.
Screening the structural and chemical space for potential new material candidates is often facilitated by high-throughput methods.
Fast and still precise computations are a main tool for such screenings and often start with a geometry relaxation to find the nearest low-energy configuration relative to the input structure.
In part I of this work, a new constrained geometry relaxation is presented which maintains the perfect symmetry of a crystal, saves time and resources as well as enables relaxations of meta-stable phases and systems with local symmetries or distortions.
Apart from improving such computations for a quicker screening of the materials space, better usage of existing data is another pillar that can accelerate novel materials discovery.
While many different databases exists that make computational results accessible, their usability depends largely on how the data is presented.
We here investigate how semantic technologies and graph representations can improve data annotation.
A number of different ontologies and knowledge graphs are developed enabling the semantic representation of crystal structures, materials properties as well experimental results in the field of heterogeneous catalysis.
We discuss the breakdown of the knowledge-graph approach when knowledge is created using artificial intelligence and propose an intermediate information layer.
The underlying ontologies can provide background knowledge for possible autonomous intelligent agents in the future.
We conclude that making materials science data understandable to machines is still a long way to go and the usefulness of semantic technologies in the domain of materials science is at the moment very limited.
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