Separation of Single-Walled Carbon Nanotubes By Electronic Type Using Conjugated Polymers

Rice, Nicole

11 1900

Since their discovery over two decades ago, single-walled carbon nanotubes (SWNTs) have become one of the most investigated nanomaterials in materials science. Their exotic optical, electrical, thermal and mechanical properties afford them amazing potential in a variety of different fields. Current SWNT synthetic processes produce heterogeneous mixtures of both semiconducting and metallic SWNTs. The mixed electronic nature of these materials, combined with their limited solubility, has significantly hampered the realization of many applications and necessitates the development of post-synthetic purification techniques. Conjugated polymers offer a significant advantage over other proposed strategies in that not only do they provide a cheaper and scalable route towards the isolation of SWNTs, but they also allow for the preparation of materials with novel properties. Polyfluorenes have been extensively investigated in the literature due to their preference towards dispersing semiconducting SWNTs; however, these dispersions are often quite dilute, and the polyfluorene structure is incompatible with certain device applications for SWNTs. Poly(2,7-carbazole)s offer a viable alternative to polyfluorenes for the purification of bulk SWNT material. At the time of this thesis, there have been relatively few reports investigating the interactions of poly(2,7-carbazole)s with SWNTs, and the majority of examples in the literature have suffered from poor stability and complex dispersal procedures due to the inherent insolubility of the 2,7-carbazole structure. The work presented in this thesis involved the preparation and characterization of a novel poly(2,7-carbazole) structure that displayed excellent solubility in a variety of organic solvents, allowing for the preparation of extremely stable and relatively concentrated dispersions of SWNTs. Thorough characterization of the supramolecular complexes through absorbance, photoluminescence and Raman spectroscopies determined that this polymer preferentially disperses semiconducting SWNTs. A second objective of this work was to investigate how modification of various parameters (including polymer structure, molecular weight and the type of SWNTs) can influence the quality of the resultant composite dispersions. One important study performed was to investigate how the electronic nature of the polymer backbone can affect the separation of SWNTs by electronic type. We demonstrate for the first time that by incorporating an electron-poor functionality into a polyfluorene it is possible to change from dispersing only semiconducting SWNTs to solubilizing both electronic types. This investigation highlights the potential importance of incorporating electron-poor functionalities in the development of polymeric systems that can selectively discriminate metallic SWNTs, which remains a challenging endeavor at the time of this thesis publication. / Thesis / Doctor of Philosophy (PhD)

Single-Walled Carbon Nanotubes

Conjugated Polymer

Supramolecular Structures

Structure-Property Relationships

REINFORCEMENT OF MELT-BLEND COMPOSITES; POLYMER-FILLER INTERACTIONS, PHASE BEHAVIOR, AND STRUCTURE-PROPERTY RELATIONSHIPS

Henry, Milliman W.

January 2011

No description available.

Polymers

Polymer composites

polymer blends

structure-property relationships

phase behavior

solubility parameters

REINFORCEMENT OF MELT-BLEND COMPOSITES; POLYMER-FILLER INTERACTIONS, PHASE BEHAVIOR, AND STRUCTURE-PROPERTY RELATIONSHIPS

Milliman, Henry

31 January 2012

No description available.

Chemistry

Materials Science

Polymers

POSS

composites

blends

structure-property relationships

phase behavior

Hansen solubility parameters

Structure-Property-Transfection Relationships in Polycation-mediated Non-viral DNA Delivery

Layman, John

12 December 2008

Non-viral gene delivery agents, such as cationic polyelectrolytes, are attractive replacements to viruses due to the absence of potential immunogenic risk and the ability to tune their macromolecular structure. Although non-viral vectors possess numerous design advantages, several investigators have shown that transfer efficiencies are considerably lower when compared to viral vectors. The work reported in this dissertation aims to fundamentally understand the underlying structure-transfection relationships involved in polycation-mediated gene delivery. Efforts focused on the influence of molecular weight, macromolecular topology, carbohydrate modifications, and charge density on the overall transfection activity in vitro. Several families of polycations were synthesized in order to correlate chemo-physical characterization with transfection results. Results revealed that seemingly small changes in the structure of cationic polyelectrolytes can have profound consequences on their transfection activity. / Ph. D.

gene delivery

plasmid DNA

polyelectrolytes

non-viral agents

aqueous characterization

structure-property relationships

Cresol Novolac/Epoxy Networks: Synthesis, Properties, and Processability

Lin-Gibson, Sheng

27 April 2001

Void-free phenolic networks have been prepared by the reaction of phenolic novolac resins with various diepoxides. The stoichiometric ratio can be adjusted to achieve networks with good mechanical properties while maintaining excellent flame retardance. A series of linear, controlled molecular weight, 2,6-dimethylphenol endcapped cresol novolac resins have been synthesized and characterized. The molecular weight control was achieved by adjusting the stoichiometric ratio of cresol to 2,6-dimethylphenol and using an excess of formaldehyde. A dynamic equilibrium reaction was proposed to occur which allowed the targeted molecular weight to be obtained. A 2000 g/mol ortho-cresol novolac resin was crosslinked by a diepoxide oligomer and by an epoxidized phenolic oligomer in defined weight ratios and the structure-property relationships were investigated. The networks comprised of 60 or 70 weight percent cresol novolac exhibited improved fracture toughness, high glass transition temperatures, low water uptake, and good flame retardance. The molecular weights between crosslinks were also determined for these networks. The stress relaxation moduli were measured as a function of temperature near the glass transition temperatures. Crosslink densities as well as the ability to hydrogen bond affect the glassy moduli of these networks. Rheological measurements indicated that cresol novolac/epoxy mixtures have an increased processing window compared to phenolic novolac/epoxy mixtures. Maleimide functionalities were incorporated into cresol novolac oligomers, and these were crosslinked with bisphenol-A epoxy. The processability of oligomers containing thermally labile maleimides were limited to lower temperatures. However, sufficiently high molecular weight oligomers were necessary to obtain good network mechanical properties. Networks prepared from 1250 g/mol cresol novolac containing maleimide functionilities and epoxy exhibited good network properties and could be processed easily. Latent triphenylphosphine catalysts which are inert at processing temperatures (~140°C) but possess significant catalytic activity at cure temperatures 180-220°C were necessary for efficient composite fabrication using phenolic novolac/epoxy matrix resins. Both sequestered catalyst particles and sizings were investigated for this purpose. Phenolic novolac/epoxy mixtures containing sequestered catalysts exhibited significantly longer processing time windows than those containing free catalysts. The resins also showed accelerated reaction rates in the presence of sequestered catalysts at cure temperatures. Trihexylamine salt of a poly(amic acid) was sized onto reinforcing carbon fibers and the composite properties indicated that fast phenolic novolac/epoxy cure could be achieved in its presence. / Ph. D.

composite

latent catalyst

flame retardance

phenolic

structure-property relationships

epoxy

Cresol novolac

controlled molecular weight

Estudo do mecanismo de ação antirradicalar de betalaínas / Study of the mechanism of antiradical action of betalains

Nakashima, Karina Kinuyo

21 December 2015

Foi preparada uma série de quatro betalaínas com o objetivo de determinar o efeito da metilação do nitrogênio imínico e da presença de uma hidroxila fenólica na posição 3 do anel aromático sobre a estabilidade e propriedades antirradicalares, fotofísicas e redox desta classe de pigmentos vegetais. O estudo destes compostos, chamados de m-betalainofenol, N-metil-m-betalainofenol, fenilbetalaína e N-metil-fenilbetalaína, revelou que os derivados metilados apresentam um deslocamento hipsocrômico sutil dos máximos de absorção e fluorescência em relação aos compostos não metilados. Os deslocamentos de Stokes são maiores em cerca de 4 kJ mol-1 para os derivados metilados e os rendimentos quânticos de fluorescência cerca de três vezes menores. A hidrólise destas betalaínas foi investigada na faixa de pH entre 3 e 7. Todas as betalaínas são mais persistentes em pH = 6 e a metilação da porção imínica aumenta significativamente a estabilidade da betalaína em meio aquoso. A presença da porção fenólica, em comparação a um grupo fenila, não afeta as propriedades fotofísicas dos compostos e tem um efeito menos pronunciado do que o da metilação sobre a estabilidade destes em meio aquoso. O comportamento eletroquímico dos compostos foi estudado por voltametria cíclica, nas mesmas condições de pH. A N-metilação foi novamente mais significativa do que a hidroxilação, provocando aumento de até 200 mV no potencial de pico anódico. O aumento do pH diminuiu o potencial de pico anódico dos quatro compostos, com uma razão entre prótons e elétrons igual a 1 para a maioria dos picos. A capacidade antirradicalar foi quantificada pelo ensaio colorimétrico TEAC baseado na redução de ABTS•+. Os dois derivados N-metilados apresentaram, em média, o mesmo valor de TEAC, apesar de um ser fenólico e o outro não. Já entre os não metilados, que têm TEAC de 2 a 3 unidades inferior à dos outros, a presença do fenol provoca elevação da capacidade antirradicalar. Os resultados sugerem a participação dos elétrons do anel 1,2,3,4-tetraidropiridínico, acoplados ao próton do nitrogênio imínico na ação antirradicalar de betalaínas. / A series of four artificial betalains was prepared in order to determine the effect of imine nitrogen methylation and phenyl hydroxylation (position 3) over stability and antiradical, photophysical and redox properties of this class of natural pigments. The study of m-betalainophenol, N-methyl-m-betalainophenol, phenylbetalain and N-methylbetalain, revealed that the methylated compounds present a small hypsochromic shift of both absorption and fluorescence maxima when compared to the others. The Stokes shifts are around 4 kJ mol-1 higher for methylated betalains, whereas the quantum yields are approximately three times lower. Their hydrolysis was investigated between pH 3 and 7. All compounds are more persistent in pH = 6, and imine methylation increases the overall stability in aqueous medium. The presence of a phenol group, in comparison with a phenyl substituent, has a minor effect on the photophysical properties of betalains and has a less pronounced effect over stability than that of methylation. The electrochemical behavior was studied by cyclic voltammetry, in the same pH range, and is also more significantly affected by methylation, rather than by hydroxylation. Methylation increases anodic peak potential up to 200 mV, and the potential is also much higher in more acidic media for all compounds. The number of protons involved in the electrochemical oxidation is the same as the number of electrons for most peaks The antiradical capacity was quantified using the TEAC assay, and ABTS•+ as radical. The methylated betalains presented, in average, the same TEAC value, although only one of them is phenolic. Among the non methylated, which are 2 to 3 units more efficient than the others, the phenolic one has a greater TEAC. These results suggest a participation of the 1,2,3,4-tetraidropiridinic ring electrons in the oxidation by ABTS•+, coupled to the imine nitrogen proton.

Antioxidantes

Antioxidants

Antiradical capacity

Betalaínas

Betalains

Capacidade antirradicalar

Ensaio TEAC

Relações estrutura-propriedade

Structure-property relationships

TEAC assay

Study of the mechanism of acid coagulation of Hevea latex and of the rheological properties of resulting gels / Etude du mécanisme de coagulation acide du latex d’Hévéa et des propriétés rhéologiques des gels résultants

Reis, Guilherme de Oliveira

10 December 2015

Latex d’Hevea brasiliensis est composé principalement de particules de caoutchouc dont le noyau est constitué de cis-1,4-polyisoprène et la membrane de composés dit non-isoprène. Sa stabilité dans l'arbre est assurée par les charges négatives de la membrane en raison de la présence de protéines et de lipides. Le latex d’Hevea brasiliensis coagule après acidification pour former un gel colloïdal qui est la première étape de sa transformation en caoutchouc naturel.Dans cette thèse, nous avons étudié l’agrégation et la gélification induite par ajout d’un acide et les propriétés des gels obtenus. Pour cela, un latex de caoutchouc naturel commercial constitué par des particules de caoutchouc (1 µm de diamètre), a été utilisée. L'agrégation a été induite par l'hydrolyse d'un composé appelé glucano-delta-lactone (GDL). Cette agrégation a été suivie par différentes techniques basées sur la diffusion de la lumière (turbidimétrie, DWS, SLS). La gélification a été suivie in situ par la rhéologie. Ensuite, les propriétés rhéologiques de gels colloïdaux formés à pH 4 ont été caractérisées dans les régimes linéaires et non-linéaires.La dépendance à la fraction volumique et le pH de l'apparition de l'agrégation ont été observée. La non-redispersion des agrégats montre les interactions fortes entre les particules de caoutchouc. Trois comportements d’état différents (solution stable, la séparation de phase et gel) peuvent être prédits à partir d'un diagramme d’état fraction volumique-pH qui a été établi pendant 5 semaines. L'état de gel présente une structure fractale, caractérisé par une relation de loi de puissance entre le module élastique G' et la fraction volumique. Pour des fortes déformations, une réorganisation irréversible sous contrainte a abouti à un durcissement irréversible du matériau. Nous avons observé par rheo-ultrasound qu'au-dessus de 50% de déformation, une déstructuration homogène est produite dans le gel. / Natural rubber latex is mainly composed by rubber particles whose core is made of cis-1,4-polyisoprene and the shell of non-isoprene compounds. It stability in the tree is provided by the negative charge of the shell due to the presence of proteins and lipids. Natural rubber latex coagulates after acidification to form a colloidal gel that is the first step of its transformation into natural rubber.In this PhD thesis, we studied this acid-induced aggregation and gelation and the properties of the resulting gels. For this, a commercial natural rubber latex composed by rubber particles (1 µm in diameter), was used. Aggregation was induced by hydrolysis of a compound called glucano-delta-lactone (GDL). The aggregation was followed by different techniques based on light scattering (turbidimetry, DWS, SLS). Gelation was followed in situ by rheology. Then, the rheological properties of colloidal gels formed at pH 4 were characterized in the linear and non-linear regimes.Dependence to the volume fraction and the pH of the onset of aggregation was observed. The non-redispersion of aggregates proves the strong interactions between rubber particles. Three different state behaviors (stable solution, phase separation and gel) can be predicted from a state diagram pH-volume fraction that was established over 5 weeks. The gel state exhibits a fractal structure, characterized by a power law relationship between the elastic modulus G’ and the volume fraction. At high deformations, an irreversible reorganization under stress resulted in an irreversible strain hardening of the material. We observed by rheo-ultrasound that above 50% deformation, an homogenous destructuration occurred in the gel.

Latex

Suspension colloïdale

Gel

Durcissement irreversible

Rheologie

Relations structure-Propriété

Latex

Colloidal suspension

Gel

Strain hardening

Rheology

Structure-Property relationships

Thermodynamic Property Prediction for Solid Organic Compounds Based on Molecular Structure

Goodman, Benjamin T.

11 November 2003

A knowledge of thermophysical properties is necessary for the design of all process units. Reliable property prediction methods are essential because reliable experimental data are often not available due to concerns about measurement difficulty, cost, scarcity, safety, or environment. In particular, there is a lack of prediction methods for solid properties. Predicted property values can also be used to fill holes in property databases to understand more fully compound characteristics. This work is a comprehensive analysis of the prediction methods available for five commonly needed solid properties. Where satisfactory methods are available, recommendations are made; where methods are unsatisfactory in scope or accuracy, improvements have been made or new methods have been developed. In the latter case, the following general scheme has been used to develop correlations: extraction of a training set of experimental data of a specific accuracy from the DIPPR 801 database, selection of a class of equations to use in the correlation, refinement of the form of the equation through least squares regression, selection of the chemical groups and/or molecular descriptors to be used as independent variables, calculation of coefficient values using the training set, addition of groups where refinement is needed, and a final testing of the resultant correlation against an independent test set of experimental data. Two new methods for predicting crystalline heat capacity were created. The first is a simple power law method (PL) that uses first-order functional groups. The second is derived as a modification of the Einstein-Debye canonical partition function (PF) that uses the same groups as the PL method with other descriptors to account for molecule size and multiple halogens. The PL method is intended for the temperature range of 50 to 250 K; the PF method is intended for temperatures above 250 K. Both the PL and PF methods have been assigned an uncertainty of 13% in their preferred temperature ranges based on comparisons to experimental data. A method for estimating heat of sublimation at the triple point was created using the same groups as used in the heat capacity PF method (estimated to have an error of 13%). This method can be used in conjunction with the Clausius-Clapeyron equation to predict solid vapor pressure. Errors in predicted solid vapor pressures averaged about 44.9%. As most solid vapor pressures are extremely small, on the order of one Pascal, this error is small on an absolute scale. An improvement was developed for an existing DIPPR correlation between solid and liquid densities at the triple point. The new correlation improves the prediction of solid density at the triple point and permits calculation of solid densities over a wide range of temperatures with an uncertainty of 6.3%. Based on the analysis of melting points performed in this study, Marrero and Gani's method is recommended as the primary method of predicting melting points for organic compounds (deviation from experimental values of 12.5%). This method can be unwieldy due to the large number of groups it employs, so the method of Yalkowsky et al. (13.9% deviation) is given a secondary recommendation due to its broad applicability with few input requirements.

chemical engineering

thermodynamics

QSPR

group contributions

solid phase

organic compounds

property prediction

Chemical Engineering

Design and Characterisation of new Anode Materials for Lithium-Ion Batteries

Fransson, Linda

January 2002

<p>Reliable ways of storing energy are crucial to support our modern way of life; lithium-ion batteries provide an attractive solution. The constant demand for higher energy density, thinner, lighter and even more mechanically flexible batteries has motivated research into new battery materials. Some of these will be explored in this thesis.</p><p>The main focus is placed on the development of new anode materials for lithium-ion batteries and the assessment of their electrochemical and structural characteristics. The materials investigated are: natural Swedish graphite, SnB₂O₄ glass and intermetallics such as: Cu₆Sn₅, InSb, Cu₂Sb, MnSb and Mn₂Sb. Their performances are investigated by a combination of electrochemical, <i>in si</i>tu X-ray diffraction and Mössbauer spectroscopy techniques, with an emphasis on the structural transformations that occur during lithiation.</p><p>The intermetallic materials exhibit a lithium insertion/metal extrusion mechanism. The reversibility of these reactions is facilitated by the strong structural relationships between the parent compounds and their lithiated counterparts. Lithiation of a majority of the intermetallics in this work proceeds via an intermediate ternary phase. The intermetallic electrodes provide high volumetric capacities and operate at slightly higher voltages vs. Li/Li⁺ than graphite. This latter feature forms the basis for a safer system.</p><p>Jet-milling of natural Swedish graphite results in decreased particle and crystallite size, leading to improved performance; the capacity is close to the theoretical capacity of graphite. Jet-milled graphite also shows an enhanced ability to withstand high charging rates.</p>

Chemistry

in situ X-ray diffraction

graphite

Li-ion battery

anode materials

intermetallics

structure-property relationships

Kemi

Chemistry

Kemi

Design and Characterisation of new Anode Materials for Lithium-Ion Batteries

Fransson, Linda

January 2002

Reliable ways of storing energy are crucial to support our modern way of life; lithium-ion batteries provide an attractive solution. The constant demand for higher energy density, thinner, lighter and even more mechanically flexible batteries has motivated research into new battery materials. Some of these will be explored in this thesis. The main focus is placed on the development of new anode materials for lithium-ion batteries and the assessment of their electrochemical and structural characteristics. The materials investigated are: natural Swedish graphite, SnB2O4 glass and intermetallics such as: Cu6Sn5, InSb, Cu2Sb, MnSb and Mn2Sb. Their performances are investigated by a combination of electrochemical, in situ X-ray diffraction and Mössbauer spectroscopy techniques, with an emphasis on the structural transformations that occur during lithiation. The intermetallic materials exhibit a lithium insertion/metal extrusion mechanism. The reversibility of these reactions is facilitated by the strong structural relationships between the parent compounds and their lithiated counterparts. Lithiation of a majority of the intermetallics in this work proceeds via an intermediate ternary phase. The intermetallic electrodes provide high volumetric capacities and operate at slightly higher voltages vs. Li/Li+ than graphite. This latter feature forms the basis for a safer system. Jet-milling of natural Swedish graphite results in decreased particle and crystallite size, leading to improved performance; the capacity is close to the theoretical capacity of graphite. Jet-milled graphite also shows an enhanced ability to withstand high charging rates.

Chemistry

in situ X-ray diffraction

graphite

Li-ion battery

anode materials

intermetallics

structure-property relationships

Kemi

Chemistry

Kemi