Synthesis, Processing, and Properties of Silicon-Containing Phthalonitrile Resins

Monzel, William Jacob

01 February 2019

Hybrid inorganic-organic resins may provide higher temperature performance in oxidizing environments than their organic counterparts. Phthalonitrile (PN) polymers are excellent candidates for hybridization due to their high thermal stability and glass transition temperatures and their need for improved long-term oxidative stability and toughness. In this work phenyl-substituted organosilicon linkages were incorporated into PN monomers to investigate their effect on the processing, thermo-mechanical properties, and thermal and oxidative stability. Three hybrid silicon-containing phthalonitrile monomers were synthesized incorporating diphenoxydiphenylsilane, tetraphenylsilane, and hexaphenyldisiloxane moieties. Processability of the polymers was highly dependent on catalyst content and an ideal concentration was determined. The impact on glass transition, coefficient of thermal expansion, stability in TGA, and long-term oxidative stability at 250 °C was evaluated. As-synthesized materials performed significantly better than polymers produced from purified monomers. Degradation of the tetraphenylsilane phthalonitrile monomer was examined in detail via IR-TGA and analysis of aged samples. Multiple degradations were identified involving both the organic and hybrid sections of the polymer. Synthesized materials are compared with commercial phthalonitrile reference materials and to other silicon-phthalonitriles in recent literature. Explanations of behavior and suggestions for future improvements are provided. / PHD / High temperature plastics and plastic composites are needed for electronics and aerospace components. Phthalonitriles (PNs) are one chemistry that shows promise for these applications. PN materials show excellent stability and strength at high temperatures. In this work, the inclusion of silicon-containing linkages into PN plastics was investigated with the intention of improving the properties and long-term stability in air at high temperatures. Three silicon-containing PN compounds were produced. The processing of un-cured resins was characterized and optimized. Resins were then cured at high temperatures. Each polymer’s softening point, thermal expansion, and stability in air and under inert conditions were evaluated. The effect of purity was considered, and it was found that as-produced PN plastics behaved better than highly purified PN plastics. The degradation reactions were studied during long-term exposure to high temperatures and short-term exposure to even higher temperatures. These silicon-containing PN materials were also compared with commercial PN plastics and with other PN literature. Explanations of behavior and suggestions for future improvements are provided.

High-Temperature

Polymer

Phthalonitrile

Organosilicon

Preparation and Functionalization of Macromolecule-Metal and Metal Oxide Nanocomplexes for Biomedical Applications

Vadala, Michael Lawrence

28 April 2006

Copolymer-cobalt complexes have been formed by thermolysis of dicobalt octacarbonyl in solutions of copolysiloxanes. The copolysiloxane-cobalt complexes formed from toluene solutions of PDMS-b-[PMVS-co-PMTMS] block copolymers were annealed at 600-700 °C under nitrogen to form protective siliceous shells around the nanoparticles. Magnetic measurements after aging for several months in both air and in water suggest that the ceramic coatings do protect the cobalt against oxidation. However, after mechanical grinding, oxidation occurs. The specific saturation magnetization of the siliceous-cobalt nanoparticles increased substantially as a function of annealing temperature, and they have high magnetic moments for particles of this size of 60 emu g⁻¹ Co after heat-treatment at temperatures above 600 °C. The siliceous-cobalt nanoparticles can be re-functionalized with aminopropyltrimethoxysilane by condensing the coupling agent onto the nanoparticle surfaces in anhydrous, refluxing toluene. The concentration of primary amine obtained on the surfaces is in reasonable agreement with the charged concentrations. The surface amine groups can initiate L-lactide and the biodegradable polymer, poly(L-lactide), can be polymerized directly from the surface. The protected cobalt surface can also be re-functionalized with poly(dimethylsiloxane) and poly(ethylene oxide-co-propylene oxide) providing increased versatility for reacting polymers and functional groups onto the siliceous-cobalt nanoparticles.Phthalonitrile containing graft copolysiloxanes were synthesized and investigated as enhanced oxygen impermeable shell precursors for cobalt nanoparticles. The siloxane provided a silica precursor whereas the phthalonitrile provided a graphitic precursor. After pyrolysis, the surfaces were silicon rich and the complexes exhibited a substantial increase in Ms. Early aging data suggests that these complexes are oxidatively stable in air after mechanical grinding. Aqueous dispersions of macromolecule-magnetite complexes are desirable for biomedical applications. A series of vinylsilylpropanol initiators, where the vinyl groups vary from one to three, were prepared and utilized for the synthesis of heterobifunctional poly(ethylene oxide) oligomers with a free hydroxy group on one end and one to three vinylsilyl groups on the other end. The oligomers were further modified with carboxylic acids via ene-thiol addition reactions while preserving the hydroxyl functionality at the opposite terminus. The resulting carboxylic acid heterobifunctional PEO are currently being investigated as possible dispersion stabilizers for magnetite in aqueous media. / Ph. D.

poly(ethylene oxide)

cobalt

phthalonitrile

polysiloxane

nanoparticle

Density Functional Theory Study of Vibrational Spectra: 9. Structures and Vibrational Assignments of Dicyanobenzenes

Higgins, James, Zhou, Xuefeng, Liu, Ruifeng

01 January 1997

Density functional theory BLYP and ab initio HF calculations have been carried out to investigate the structures and vibrational spectra of dicyanobenzenes. The calculated results are in good agreement with reliable experimental data and indicate that the benzene rings of all three isomers are only slightly distorted by the two cyano groups. Vibrational frequencies calculated by BLYP/6-31G* force fields agree very well with experimental results, with a mean deviation of about 14 cm-1 for non-CH stretching modes. On the basis of agreement between the calculated and observed results, assignments of the fundamental vibrational modes were examined and some reassignments were proposed. This study demonstrates that the density functional theory BLYP calculation is a powerful approach to understanding the vibrational spectra of organic compounds.

1

3-dicyanobenzene

density functional theory

phthalonitrile

terephthalonitrile

vibrational assignment

Novel Novolac-Phthalonitrile and Siloxane-Phthalonitrile Resins cured with low melting Novolac Oligomers for Flame Retardant Structural Thermosets

Hardrict, Shauntrece Nicole

15 January 2004

The chemical modification of low molecular weight novolac oligomers and siloxane/silane-containing monomers has led to novel phthalonitrile derivatives with low glass transition temperatures, ranging from -25 to 75 ºC. Multi-functional, low molecular weight phenol-formaldehyde novolac resins were blended with these novel phthalonitrile derivatives to achieve low viscosity resin blends. Moderate temperatures and rapid curing cycles were employed (200 ºC, 1 h and 225 ºC, 4h) to produce networks with high glass transition temperatures (> 250 ºC). A decrease in the sharp band at 2230 cm⁻¹, attributed to the nitrile functionality of the phthalonitrile resin, was monitored in FTIR studies and indicated the progress of the reactions. Ninety percent conversion was achieved within ~ 30 min. Thermal analysis of siloxane-phthalonitrile/novolac networks cured for 1h at 200 ºC and 4h at 225 ºC did not exhibit glass transition temperatures below 250 ºC. In dynamic TGA studies, 5% weight loss temperatures up to 418 ºC were observed, and the materials exhibited 50 to 56 % char at 800 ºC in nitrogen. Networks prepared from a resin blend containing 50 weight% of a phthalonitrile derivative of a 260 g mol⁻¹ novolac oligomer, 50 weight% of the 260 g mol⁻¹ novolac oligomer, and 1.5 mol % triphenylphosphine (based on novolac) (NOV/NOV/TPP) cured at 200 ºC for 1h, did not exhibit a Tg below 250 ºC via DSC. These networks exhibited a 5% weight loss temperature of 350 ºC, and 70 % char at 800 ºC in TGA studies under nitrogen. This degree of char formation makes these materials appealing for use in carbon-carbon composites. Post-curing these networks at 200 ºC for 1h, and then at 225 ºC for 4h, resulted in high thermo-oxidative stability, with a 5% weight loss observed at 447 ºC and 50 % char at 800 ºC. Blending tetramethyldisiloxane phthalonitrile monomers with 260 g mol⁻¹ novolac oligomers afforded prepolymer resins with low melt viscosities, 560 mPa s at 80 ºC. Such viscosities may allow these resins to be processed via vacuum assisted resin transfer molding (VARTM) at low temperatures and heated at elevated temperatures to produce flame resistant three-dimensional networks. / Master of Science

novolac

phenolic networks

phthalonitrile

flame retardance

composite matrix

Syntheses of sulfanylphthalimide and xanthine analogues and their evaluation as inhibitors of monoamine oxidase and as antagonists of adenosine receptors / Mietha Magdalena van der Walt

Van der Walt, Mietha Magdalena

January 2013

Currently L-DOPA is the drug most commonly used for the treatment of Parkinson’s disease (PD). However, the long-term use of L-DOPA is associated with the development of motor fluctuations and dyskinesias. Treatment mainly addresses the dopaminergic features of the disease and leaves its progressive course unaffected. An optimal treatment would be a combination of both motor and non-motor symptom relief with neuroprotective properties. Two drug targets have attracted the attention for PD treatment, namely monoamine oxidase B (MAOB) and adenosine A2A receptors. MAO-B inhibitors enhance the elevation of dopamine levels after L-DOPA treatment, improve motor functions and may also possess neuroprotective properties. The antagonistic interaction between A2A and dopamine receptors in the striatopallidal pathway, which modulates motor behaviour, has also become a potential strategy for PD treatment. Blockade of the A2A receptor exerts both anti-symptomatic and neuroprotective activities and offer benefit for motor symptoms and motor complications. This thesis seeks to synthesize novel drug treatments for PD by exploring both MAO-B inhibitors and adenosine A2A receptor antagonists and to assess the prospects for drug modification to increase activity. MAO-B inhibitors - Based on a recent report that the phthalimide moiety may be a useful scaffold for the design of potent MAO-B inhibitors, the present study examines a series of 5-sulfanylphthalimide analogues as potential inhibitors of both human MAO isoforms. The results document that 5- sulfanylphthalimides are highly potent and selective MAO-B inhibitors with all of the examined compounds possessing IC50 values in the nanomolar range. The most potent inhibitor, 5- (benzylsulfanyl)phthalimide, exhibits an IC50 value of 0.0045 μM for the inhibition of MAO-B with a 427–fold selectivity for MAO-B compared to MAO-A. We conclude that 5-sulfanylphthalimides represent an interesting class of MAO-B inhibitors and may serve as lead compounds for the design of antiparkinsonian therapy. It has recently been reported that nitrile containing compounds frequently act as potent MAO-B inhibitors. In an attempt to identify additional potent and selective inhibitors of MAO-B and to contribute to the known structure-activity relationships of MAO inhibition by nitrile containing compounds, the present study examined the MAO inhibitory properties of series of novel sulfanylphthalonitriles and sulfanylbenzonitriles. The results document that the evaluated compounds are potent and selective MAO-B inhibitors with most homologues possessing IC50 values in the nanomolar range. In general, the sulfanylphthalonitriles exhibited higher binding affinities for MAO-B than the corresponding sulfanylbenzonitrile homologues. Among the compounds evaluated, 4-[(4-bromobenzyl)sulfanyl]phthalonitrile is a particularly promising inhibitor since it displayed a high degree of selectivity (8720-fold) for MAO-B over MAO-A, and potent MAO-B inhibition (IC50 = 0.025 μM). Based on these observations, this structure may serve as a lead for the development of therapies for neurodegenerative disorders such as Parkinson’s disease. Adenosine A2A receptor antagonism - Most adenosine A2A receptor antagonists belong to two different chemical classes, the xanthine derivatives and the amino-substituted heterocyclic compounds. In an attempt to discover high affinity A2A receptor antagonists for PD and to further explore the structure-activity relationships of A2A antagonism by the xanthine class of compounds, this study examines the A2A antagonistic properties of series of (E)-8-styrylxanthine, 8-(phenoxymethyl)xanthine and 8-(3- phenylpropyl)xanthine derivatives. The results document that among these series, the (E)-8- styrylxanthines are the most potent antagonists with the most potent homologue, (E)-1,3-dietyl- 7-methyl-8-[(3-trifluoromethyl)styryl]xanthine, exhibiting a Ki value of 11.9 nM. This compound was also effective in reversing haloperidol-induced catalepsy in rats. The importance of substitution at C8 with the styryl moiety was demonstrated by the finding that none of the 8- (phenoxymethyl)xanthines and 8-(3-phenylpropyl)xanthines exhibited high binding affinities for the A2A receptor. It was also concluded that (E)-8-styrylxanthines are potent A2A antagonists with particularly the 1,3-dietyl-7-methylxanthine substitution pattern being most appropriate for high affinity binding. Conclusion - The results of these studies have established that all of the sulfanylphthalimides, sulfanylphthalonitriles and sulfanylbenzonitriles examined display significant MAO-B inhibitory properties in vitro with IC50 values in the low μM to nM range. Good A2A receptor affinity was demonstrated by the xanthines containing a styryl moiety, while the phenoxymethyl and phenylpropyl xanthines exhibited poor activity. / Thesis (PhD (Pharmaceutical Chemistry))--North-West University, Potchefstroom Campus, 2013

Parkinson’s disease

Monoamine oxidase

Phthalimide

Phthalonitrile

Benzonitrile

Inhibition

Adenosine A2A receptors

Antagonist

Xanthine

Syntheses of sulfanylphthalimide and xanthine analogues and their evaluation as inhibitors of monoamine oxidase and as antagonists of adenosine receptors / Mietha Magdalena van der Walt

Van der Walt, Mietha Magdalena

January 2013

Currently L-DOPA is the drug most commonly used for the treatment of Parkinson’s disease (PD). However, the long-term use of L-DOPA is associated with the development of motor fluctuations and dyskinesias. Treatment mainly addresses the dopaminergic features of the disease and leaves its progressive course unaffected. An optimal treatment would be a combination of both motor and non-motor symptom relief with neuroprotective properties. Two drug targets have attracted the attention for PD treatment, namely monoamine oxidase B (MAOB) and adenosine A2A receptors. MAO-B inhibitors enhance the elevation of dopamine levels after L-DOPA treatment, improve motor functions and may also possess neuroprotective properties. The antagonistic interaction between A2A and dopamine receptors in the striatopallidal pathway, which modulates motor behaviour, has also become a potential strategy for PD treatment. Blockade of the A2A receptor exerts both anti-symptomatic and neuroprotective activities and offer benefit for motor symptoms and motor complications. This thesis seeks to synthesize novel drug treatments for PD by exploring both MAO-B inhibitors and adenosine A2A receptor antagonists and to assess the prospects for drug modification to increase activity. MAO-B inhibitors - Based on a recent report that the phthalimide moiety may be a useful scaffold for the design of potent MAO-B inhibitors, the present study examines a series of 5-sulfanylphthalimide analogues as potential inhibitors of both human MAO isoforms. The results document that 5- sulfanylphthalimides are highly potent and selective MAO-B inhibitors with all of the examined compounds possessing IC50 values in the nanomolar range. The most potent inhibitor, 5- (benzylsulfanyl)phthalimide, exhibits an IC50 value of 0.0045 μM for the inhibition of MAO-B with a 427–fold selectivity for MAO-B compared to MAO-A. We conclude that 5-sulfanylphthalimides represent an interesting class of MAO-B inhibitors and may serve as lead compounds for the design of antiparkinsonian therapy. It has recently been reported that nitrile containing compounds frequently act as potent MAO-B inhibitors. In an attempt to identify additional potent and selective inhibitors of MAO-B and to contribute to the known structure-activity relationships of MAO inhibition by nitrile containing compounds, the present study examined the MAO inhibitory properties of series of novel sulfanylphthalonitriles and sulfanylbenzonitriles. The results document that the evaluated compounds are potent and selective MAO-B inhibitors with most homologues possessing IC50 values in the nanomolar range. In general, the sulfanylphthalonitriles exhibited higher binding affinities for MAO-B than the corresponding sulfanylbenzonitrile homologues. Among the compounds evaluated, 4-[(4-bromobenzyl)sulfanyl]phthalonitrile is a particularly promising inhibitor since it displayed a high degree of selectivity (8720-fold) for MAO-B over MAO-A, and potent MAO-B inhibition (IC50 = 0.025 μM). Based on these observations, this structure may serve as a lead for the development of therapies for neurodegenerative disorders such as Parkinson’s disease. Adenosine A2A receptor antagonism - Most adenosine A2A receptor antagonists belong to two different chemical classes, the xanthine derivatives and the amino-substituted heterocyclic compounds. In an attempt to discover high affinity A2A receptor antagonists for PD and to further explore the structure-activity relationships of A2A antagonism by the xanthine class of compounds, this study examines the A2A antagonistic properties of series of (E)-8-styrylxanthine, 8-(phenoxymethyl)xanthine and 8-(3- phenylpropyl)xanthine derivatives. The results document that among these series, the (E)-8- styrylxanthines are the most potent antagonists with the most potent homologue, (E)-1,3-dietyl- 7-methyl-8-[(3-trifluoromethyl)styryl]xanthine, exhibiting a Ki value of 11.9 nM. This compound was also effective in reversing haloperidol-induced catalepsy in rats. The importance of substitution at C8 with the styryl moiety was demonstrated by the finding that none of the 8- (phenoxymethyl)xanthines and 8-(3-phenylpropyl)xanthines exhibited high binding affinities for the A2A receptor. It was also concluded that (E)-8-styrylxanthines are potent A2A antagonists with particularly the 1,3-dietyl-7-methylxanthine substitution pattern being most appropriate for high affinity binding. Conclusion - The results of these studies have established that all of the sulfanylphthalimides, sulfanylphthalonitriles and sulfanylbenzonitriles examined display significant MAO-B inhibitory properties in vitro with IC50 values in the low μM to nM range. Good A2A receptor affinity was demonstrated by the xanthines containing a styryl moiety, while the phenoxymethyl and phenylpropyl xanthines exhibited poor activity. / Thesis (PhD (Pharmaceutical Chemistry))--North-West University, Potchefstroom Campus, 2013

Parkinson’s disease

Monoamine oxidase

Phthalimide

Phthalonitrile

Benzonitrile

Inhibition

Adenosine A2A receptors

Antagonist

Xanthine

Cobalt Nanoparticle-Macromolecular Complexes and Their Conversion to Oxidatively Stable Entities

Baranauskas, Victor Vincent

29 April 2005

The goal of the research presented in this dissertation was to synthesize novel macromolecular materials that would afford oxidative stability to magnetic cobalt nanoparticles under ambient conditions. The cobalt nanoparticles were formed via the thermolysis of Co2(CO)8 in concentrated solutions of toluene containing the macromolecular dispersion stabilizers. The copolymers were designed to encapsulate the nanoparticles with a number of thin protective coatings to prevent their undesirable oxidation under ambient condtions. Cobalt nanoparticles encased with an organic glass were synthesized by stabilizing cobalt nanoparticles with poly(methyl methacrylate-co-2-vinylpyridine-g-dimethylsiloxane) whereas nanoparticles encapsulated with triazine networks were formed via the thermal treatment of cobalt particles complexed with poly(styrene-b-4-vinylphenylcyanate). Cobalt nanoparticles coated with a combination of carbonaceous and silica char were obtained by pyrolyzing cobalt particles stabilized with poly (4-vinylphenoxyphthalonitrile-co-4-vinylphenoxytriethoxysilane-g-dimethylsiloxane) graft copolymers. Moreover, cobalt nanoparticles encapsulated with either phthalonitrile networks or graphitic char were prepared via the thermal treatment of nanoparticles stabilized with poly(styrene-b-4-vinylphenoxyphthalonitrile). Oxidatively-stable, magnetic cobalt nanoparticle complexes may be prepared by heating cobalt nanoparticles encapsulated in poly(styrene-b-4-vinylphenoxyphthalonitrile) block copolymers at elevated temperatures. The block copolymers were synthesized through the sequential anionic polymerization of styrene and tert-butyldimethylsilyloxystyrene. The silyl ether protecting groups on the second block were hydrolyzed under acidic conditions to afford poly(styrene-b-4-vinylphenol), and the pendent phenols of the diblock copolymer were chemically modified with 4-nitrophthalonitrile to afford poly(styrene-b-4-vinylphenoxyphthalonitrile). Stable suspensions of ~8-10 nm diameter cobalt metal nanoparticles were formed by thermolysis of dicobalt octacarbonyl in solutions of toluene containing poly(styrene-b-4-vinylphenoxyphthalonitrile). The cobalt-polymer nanoparticle complexes were pyrolyzed under argon to afford highly magnetic cobalt nanoparticles encased in graphitic coatings. Magnetic susceptibility measurements indicate that the cobalt-graphitic particles are oxidatively-stable and retain their high saturation magnetizations (~ 95-100 emu g-1) for at least a year under ambient conditions. / Ph. D.

copolymer

cobalt

dispersion stabilizer

pyrolysis

oxidative stability

magnetic

saturation magnetization

phthalonitrile

nanoparticle

High Performance Materials Containing Nitrile Groups

Sumner, Michael Jameson

24 April 2003

The objective of the research described in this thesis has been to improve the toughness of phenolic networks while maintaining flame resistance. A four step synthetic scheme has been developed to prepare 4,4′-Bis(3,4-dicyanophenoxy)biphenyl(biphenoxyphthalonitrile). A 700 g mol-1 novolac oligomer was cured with relatively low concentrations of this reagent (~20 wt %) into high Tg (~190 °C) networks. The curing reaction was attrubuted to nucleophilic attack of the phenolic hydroxyl on the nitrile groups of the phthalonitrile resulting in the formation of heterocylic rings. TGA and cone calorimetry demonstrated that these networks have excellent thermo-oxidative stability. Further goals were to develop halogen-free, flame retardant monomers for improving the thermo-oxidative resistance of polystyrene and dimethylacrlyate/styrene(vinyl ester) networks. 4-Vinylphenoxyphthalonitrile, a phthalonitrile derivative of styrene, was synthesized. FTIR has been utilized to demonstrate this new monomer co-cured into vinyl ester networks in free radical thermosetting polymerizations. Upon post-curing the networks between 200-260 °C for ~1.5 h, the nitrile groups reacted to form heterocyclic crosslinks. TGA and cone calorimetry demonstrated that the 4-vinylphenoxyphthalonitrile substantially improved the flame resistance of vinyl ester networks. Copolymerizations of styrene and 4-vinylphenoxyphthalonitrile were conducted at 75 °C for 24 h using 0.5 wt % AIBN in chlorobenzene. Dynamic TGA at 10 °C min-1 in air showed that copolymers containing 10 and 25 mole % of 4-vinylphenoxyphthalonitrile had increased initial weight loss temperatures in air by (~50 °C higher) and increased the char yield between 400-600 °C. High molecular weight nitrile-functional, (hexafluoroisopropylidene)diphenol based aromatic poly(arylene ether)s with pendent sulfonic acid groups were prepared by nucleophilic step copolymerization of 4,4′-(hexafluoroisopropylidene)diphenol, 2,6-dichlorobenzonitrile, and 3,3′-disulfonate-4,4′-dichlorodiphenylsulfone under basic conditions in N-methyl-2-pyrrolidinone at 200 °C. A series of these materials with systematically varied concentrations of the sulfonic acid moieties showed increased glass transition temperatures, proton conductivities, and hydrophilicities as a function of disulfonation. Atomic force microscopy (AFM) demonstrated that the acidified copolymer with 35 mole % of disulfonated units was phase separated into a co-continuous morphology of hydrophobic and hydrophilic domains. / Ph. D.

vinyl ester networks

phthalonitrile

polystyrene copolymers

phenolic networks

proton conducting membranes