Host-Guest Systems Based on Crown Ether, Cryptand, and Pseudocryptand Hosts with Paraquat, Diquat, Secondary Ammonium, and Monopyridinium Salt Guests

Huang, Feihe

25 March 2005

Supramolecular host-guest chemistry is a topic of great current interest. However, the further development of host-guest chemistry is still limited by the number of available host-guest recognition motifs. This makes it necessary and valuable to find new host-guest recognition motifs and apply known host-guest recognition motifs in the preparation of novel supramolecular systems. By comparing the crystal structures of the host and its taco complex, we proved that folding is a necessary step during the formation of taco complexes. Based on the known bis(m-phenylene)-32-crown-10/paraquat recognition motif, the first solid-state supramolecular poly(taco complex) was prepared. We demonstrate not only that bis(m-phenylene)-32-crown-10-based cryptands are powerful hosts for paraquat derivatives compared with the simple crown ether, but also that cooperative complexation can be obtained with the cryptand structure. It was shown that the significant improvement in complexation was the result of the combination of the preorganization of the cryptand hosts and the introduction of additional and optimized binding sites. Furthermore, it was demonstrated that improved complexation of bis(secondary ammonium) and bisparaquat salts could also be achieved by the formation of the pseudocryptand structure. We also prepared two dimers of inclusion cryptand/paraquat complexes driven by dipole-dipole and face-to-face p-stacking interactions. An interesting complex based on dibenzo-24-crown-10 and diquat was prepared. In its crystal structure the diquat guest lies in the concave cavity provided by two dibenzo-24-crown-8 hosts. Monopyridinium-based [2]- and [3]-pseudorotaxanes were prepared based on the newly discovered bis(m-phenylene)-32-crown-10/monopyridinium salt and cryptand/monopyridinium salt recognition motifs. Inspired by the formation of solid-state taco complexes between bis(m-phenylene)-32-crown-10 and paraquat derivatives, we designed and synthesized the first cylindrical bis(crown ether) host for paraquat derivatives and studied its complexation with paraquat. We prepared three slow-exchange C3-symmetric inclusion complexes based on a newly discovered cryptand/trispyridinium recognition motif, in which 1,3,5-trispyridiniumbenzene salts act as guests. Finally the application of several new and known recognition motifs in the preparation of a supramolecular poly[3]pseudrotaxane, and the first pseudorotaxane-type supramolecular star-shaped polymer, and the first supramolecular hyperbranched polymer was discussed. / Ph. D.

Paraquat

Crown Ether

Cryptand

Pseudocryptand

Ammonium

Pyridinium

Self-Assembly

Association Constant

Diquat

Supramolecular Polymer

Pseudorotaxane

X-ray Crystallography

Direct Polymerization Of Sulfonated Poly(arylene ether) Random Copolymers And Poly(imide)Sulfonated Poly(arylene ether) Segmented Copolymers: New Candidates For Proton Exchange Membrane Fuel Cell Material Systems

Mecham, Jeffrey B.

26 April 2001

Commercially available 4,4′-dichlorodiphenylsulfone (DCDPS) was successfully disulfonated with fuming sulfuric acid to yield 3,3′-disodiumsulfonyl-4,4′-dichlorodiphenylsulfone (SDCDPS). Subsequently, DCDPS and SDCDPS were systematically reacted with 4,4′-biphenol under nucleophilic step polymerization conditions to generate a series of high molecular weight, film-forming, ductile, ion conducting copolymers. These were converted to the acid form and investigated as proton exchange membranes for fuel cells. Hydrophilicity increased with the level of sulfonation. However, water sorption increased gradually until about 50 mole percent SDCDPS was incorporated, and thereafter showed a large increase to yield water soluble materials for the 100% SDCDPS system. Atomic force microscopy (AFM) confirmed that the morphology of the copolymers displayed continuity of the hydrophilic phase at 60 mole percent SDCDPS. Conductivity measurements in the 40-50 mole percent SDCDPS range, where excellent mechanical strength was maintained, produced values of 0.1 S/cm or higher which were comparable to the control, Nafion™. These compositions also show a high degree of compatibility with heteropolyacids such as phosphotungstic acid. These inorganic compounds provide a promising mechanism for obtaining conductivity at temperatures well above the boiling point of water and membrane compositions containing them are being actively pursued. The water soluble 100% SDCDPS system was further investigated by successfully functionalizing the endgroups to afford aromatic amines via appropriate endcapping with m-aminophenol. Oligomers and polymers from 5-30 kg/mole number average molecular weight were synthesized and well characterized by NMR spectroscopy, endgroup titrations and size exclusion chromatography. The diamino-telechelic sulfonated segment was reacted with several dianhydrides and diamines to produce multiblock, hydrophobic polyimide-hydrophilic sulfonated polyarylene ether copolymers. Both ester-acid and amic acid synthesis routes were utilized in combination with spin-casting and bulk imidization. A series of tough, film-forming segmented copolymers was prepared and characterized. AFM measurements demonstrated the generation of quite well defined, nanophase-separated morphologies which were dependent upon composition as well as aging in a humid environment. Characterizations of the segmented copolymers for conductivity, and water and methanol sorption were performed and comparisons to state-of-the-art perfluorinated Nafion™ systems were made. It is concluded that the segmented or block systems have the potential to enhance certain desirable PEM characteristics in fuel cells, particularly those related to swelling, retention of mechanical strength at elevated temperatures, and critical adhesion issues in membrane electrode assemblies. / Ph. D.

Sulfonic Acid Sites

Poly(arylene ether)

Random Copolymer

Poly(imide)

Direct Copolymerization

Segmented Copolymer

Proton Exchange Membrane

Quartz Crystal Microbalance with Dissipation Monitoring Applications in Polymer Thin Films Analysis

Liu, Gehui

25 January 2022

Natural and synthetic polymers are highly related to people's daily life in every perspective and determine everyone's life quality. This study investigated the interactions between polymer thin films and other molecules, specifically natural polymer films with other components in plant and fungal cell walls, crosslinked thermoplastic films with solvent molecules, as well as commodity thermoplastic films with air and moisture during aging by a powerful surface analysis instrument, a quartz crystal microbalance with dissipation monitoring (QCM-D). The assembly and interactions of glucan and chitin are crucial for understanding the fungal infection mechanism. Adsorption of mixed-linkage glucan (MLG) onto regenerated chitin (RChitin) and cellulose (RC) surfaces were investigated by QCM-D and atomic force microscopy (AFM). MLG was irreversibly adsorbed onto both surfaces and formed soft hydrogel-like layers with viscoelastic properties. This work established a QCM-D method to mimic the assembly of natural polymers in fungal cell walls and provided insight into the interactions of these polymers with chitin and cellulose. Poly(ether imide) (PEI) has poor solvent resistance towards solvents including chloroform, dimethylformamide (DMF), dichloromethane (DCM), and N-methyl pyrrolidone (NMP). Exposure to these solvents severely affects the thermal and mechanical performances of PEI. Therefore, crosslinked PEI (X-PEI) films was prepared from azide-terminated PEI (N₃-PEI-N₃) via a thermal crosslinking reaction. X-PEIs maintain outstanding solvent resistance towards common solvents by swelling ratio tests using QCM-D. Meanwhile, the thermal and mechanical properties of X-PEI were enhanced compared to the original PEI. Photo-oxidation is one of the dominant degradation mechanisms affecting the lifespan of polymers. The effect of photooxidative aging on the physiochemical properties of low-density polyethylene (LDPE) films were investigated using QCM-D, differential scanning calorimetry (DSC), and tensile stress-strain tests. The crystallinity, mechanical properties, and weight loss were correlated to understand the aging behavior. Materials after aging showed higher tensile stress and modulus, with reduced mass and elongation properties. Particularly, the aging-induced damage of polymer chain integrity was first determined by QCM-D through the evolution of mass loss during aging, providing supports to the changes of mechanical properties under aging. / Doctor of Philosophy / Natural polymers and thermoplastics are two major materials that are highly related to modern life. The interactions of these polymers with other molecules are important research topics for people to understand and predict the material properties. This dissertation studied the following three topics using a quartz crystal microbalance with dissipation monitoring (QCM-D): 1) interactions between plant natural polymer films and polymers in fungal cell wall; 2) solvent resistance of crosslinked thermoplastic films; and 3) physiochemical changes during photo-oxidation degradation of thermoplastic films. Pathogenic fungal cells can attack beneficial plant cell hosts by adhering themselves onto the plant cells, followed by penetration and enzymatic degradation of the multilayered plant cell walls until the host is digested. Therefore, the interaction between the components in fungal and plant cell walls is critical to understand pathogenic fungal cell invasion. Adsorption of mixed-linkage glucan (MLG) onto regenerated chitin (RChitin) and cellulose (RC) surfaces was monitored by QCM-D and atomic force microscopy (AFM). An irreversible binding interaction of MLG with chitin and cellulose films and a soft hydrogel-like layer on both surfaces were observed in our work. Poly(ether imide) (PEI) is a high-performance polymer with excellent thermal and mechanical properties. However, the good solubilities in common organic solvents that facilitate reasonable processibility limits its applications in solvent-related domains. Several methods of PEI crosslinking were developed in the literature to improve solvent resistance. This study prepared crosslinked PEI (X-PEI) films from azide-terminated PEI (N₃-PEI-N₃) via a simple thermal crosslinking reaction. X-PEI had better resistance to organic solvents from QCM-D measurements and maintained good thermal and mechanical performances. Photo-oxidation from air and sunlight slowly degrades plastics, shortens their service time, and leads to environmental pollution. This work bridged the gap between molecular integrity and its effect on the overall macroscopic mechanical changes through accurate measurement of the mass loss during degradation using a QCM-D. This work is essential in ensuring polymer design and active environmental protection.

Chitin

Poly(ether imide)

Polyethylene

Thin Films

Adsorption

Crosslinking

Solvent Resistance

Photo-oxidation

Fluoromethyl ketone prodrugs: Potential new insecticides towards Anopheles gambiae

Camerino, Eugene

29 June 2015

Malaria continues to cause significant mortality in sub-Saharan Africa and elsewhere, and existing vector control measures are being threatened by growing resistance to pyrethroid insecticides. With the goal of developing new human-safe, resistance-breaking insecticides we have explored several classes of acetylcholinesterase inhibitors. In vitro assay studies demonstrate that tri- and difluoromethyl ketones can potentially inhibit An. gambiae AChE (AgAChE). These compounds inhibit the enzyme by making a covalent adduct with the catalytic serine of AChE. Trifluoromethyl ketones however are poor inhibitors of the G119S resistant mutant of AgAChE. However difluoromethyl ketones can inhibit G119S AgAChE and compound 3-10g showed an IC₅₀ value of 25.1 nM after 23h incubation time. Despite this potent inhibition of AgAChE, the tri-, di-, and (mono)fluoroketones showed very low toxicity to An. gambiae, perhaps due to hydration and rapid clearance. In an attempt to improve An. gambiae toxicity, oximes and oxime ethers of these compounds were prepared as potential prodrugs. These structures identified trifluoromethyl ketone oxime 3-2d as a potent toxin against both wild-type (G3-strain) and a multiply resistant (Akron) strain of An. gambiae. This compound is within 3-fold of the toxicity of propoxur to wild type An. gambiae (LC₅₀ values of 106 and 39 µg/mL, respectively). Most significantly, 3-2d was much more toxic than propoxur to multiply-resistant (Akron) strain An. gambiae (LC₅₀ = 112 and >5,000 µg/mL, respectively). However, thus far we have not been able to link the toxicity of these compounds to a cholinergic mechanism. Pre-incubation studies suggest that significant hydrolysis of these compounds to TFKs does not occur over 22 h at pH 7.7 or 5.5. The mechanism of action of 3-2d remains unknown. Our enzyme inhibition studies have demonstrated that 3-2d does not hydrolyze to the trifluoromethyl ketone 2-9d at pH 7.7. The high Akron toxicity of 3-2d and poor inhibition of G119S AgAChE by 2-9d argue against enzyme mediated conversion of 3-2d to 2-9d within the mosquito. Thus, we can rule out an AChE inhibition mechanism for toxicity. Additional experiments by our collaborator (Dr. Jeffrey Bloomquist, University of Florida) also rule out inhibition of mitochondrial respiration or agonism of the muscarinic acetylcholine receptor. Future work will address other potential insecticidal modes of action. / Ph. D.

Acetylcholinesterase

trifluoromethyl ketones

difluoromethyl ketones

fluoromethyl ketones

Anopheles gambiae

insecticide treated nets

malaria

pyrazoles

propoxur

insecticide resistance

oxime

oxime ether

Advanced Polymeric Membranes and Multi-Layered Films for Gas Separation and Capacitors

Shaver, Andrew Thomas

30 June 2016

The following studies describe the synthesis and properties of a family of poly(arylene ether ketone)s which are well known to have good thermal stability, mechanical durability, and other film properties. These poly(arylene ether ketone)s were functionalized with fluorine, oxidized, blended, and crosslinked to increase performance with focus on materials for polymeric capacitors and gas separation membranes. There is a need for polymeric capacitors with improved energy storage density and thermal stability. In this work, the affect of polymer molecular structure and symmetry on Tg, breakdown strength, and relative permittivity was investigated. A systematic series of four amorphous poly(arylene ether ketone)s was compared. Two of the polymers had symmetric bisphenols while the remaining two had asymmetric bisphenols. Two contained trifluoromethyl groups while the other two had methyl groups. The symmetric polymers had Tg's of approximately 160 °C while the asymmetric polymers showed higher Tg's near 180 °C. The symmetric polymers had breakdown strengths near 380 kV/mm at 150 °C. The asymmetric counterparts had breakdown strengths near 520 kV/mm even at 175 °C, with the fluorinated polymers performing slightly better in both cases. The non-fluorinated polymers had higher relative permittivities than the fluorinated materials, with the asymmetric polymers being better in both cases. Two amorphous, high glass transition, crosslinkable poly(arylene ether)s for gas purification membranes have been studied. The polymers were polymerized via step growth and contained tetramethyl bisphenol F and either 4,4'-difluorobenzophenone or 4,4'-dichlorodiphenylsulfone. The benzylic methylene group in tetramethyl bisphenol F can undergo oxidation reactions and crosslinking with UV light. The polymers were oxidized under two different conditions, one by chemical treatment using oxone and KBr and one by elevated thermal treatment in air. Thermogravimetric analysis, 1H-NMR and attenuated total reflectance Fourier transform infrared spectroscopy revealed the progress of the thermal oxidation reactions. Both polymers produced tough, ductile films and gas transport properties of the non-crosslinked linear polymers and crosslinked polymer was compared. Crosslinking was performed by irradiating polymer films for one hour on each side in air under a 100W high intensity, long-wave UV lamp equipped with a 365-nm light filter. The O2 permeability of tetramethyl bisphenol F containing non-crosslinked poly(arylene ether ketone) was 2.8 Barrer, with an O2/N2 selectivity of 5.4. Following UV crosslinking, the O2 permeability decreased to 1.8 Barrer, and the O2/N2 selectivity increased to 6.2. Poly(2,6-dimethyl-1,4-phenylene oxide) (PPO) is a commercial polymer that is utilized for gas separation membranes. It has a relatively high free volume with high gas permeabilities but suffers from low gas selectivities. In this study, PPO polymers with number average molecular weights of 2000, 6000, 17,000, 19,000 and 22,000 were synthesized and blended with a poly(arylene ether ketone) synthesized from bisphenol A and difluorobenzophenone (BPA-PAEK) to make UV-crosslinkable films. The ketone and benzylic methylene groups on the BPA-PAEK and the PPO polymers respectively formed crosslinks upon exposure to broad wavelength UV light. The crosslinked blends had increased selectivities over their linear counterparts. DSC thermograms showed that the blends with all but the lowest molecular weight PPO had two Tg's, thus suggesting that two phases were present, one high in PBA-PAEK and the other high in PPO composition. The PBA-PAEK blend with the 2000 Mn PPO showed only one Tg between the two control polymers. Despite the immiscibility of these films, the gel fractions after UV exposure were high. Gel fractions as a function of the amount of the 22,000 Mn PPO were explored and did not show any significant change. UV spectroscopy of the individual components and the blends showed that more broad wavelength light was transmitted through the PPO component, so it was reasoned that films that was high in PPO composition crosslinked to deeper depths. The O2/N2 permeabilities and selectivities were measured for the linear and crosslinked films. Between the 33/67, 67/33, and 90/10 22k PPO/BPA PAEK crosslinked blended films, the 90/10 PPO/BPA PAEK gained the most selectivity and maintained a larger amount of its permeability. In comparison to commercial gas separation polymers, the non-crosslinked 33/67 22,000 Mn PPO/BPA PAEK blend outperformed polysulfone and cellulose acetate with a 2.45 degree of acetylation. Overall, we were able to blend a small amount of BPA PAEK with the commercially used PPO to create a mechanically robust crosslinked polymer film. / Ph. D.

Fluorinated Dielectric Materials

Microlayer Coextrusion

Poly(Arylene Ether Ketone)s

Gas Separation

PPO

Poly(dimethyl phenylene oxide)

Synthesis and Characterization of Hydrophobic-Hydrophilic Multiblock Copolymers for Proton Exchange Membrane Applications

Chen, Yu

17 October 2011

Proton exchange membrane fuel cells (PEMFCs) have been extensively studied as clean, sustainable and efficient power sources for electric vehicles, and portable and residential power sources. As one of the key components in PEMFC system, proton exchange membranes (PEMs) act as the electrolyte that transfers protons from the anode to the cathode. The state-of-art commercial PEM materials are typically based on perfluorinated sulfonic acid containing ionomers (PFSAs), represented by DuPont's Nafion®. Despite their good chemical stability and proton conductivity at high relative humidity (RH) and low temperature, several major drawbacks have been observed on PFSAs, such as high cost, high fuel permeability, insufficient thermo-mechanical properties above 80°C, and low proton conductivity at low RH levels. Therefore the challenge lies in developing alternative PEMs which feature associated ionic domains at low hydration levels. Nanophase separated hydrophilic-hydrophobic block copolymer ionomers are believed to be desirable for this purpose Three series of hydrophobic/hydrophillic, partially fluorinated/sulfonated multiblock copolymers were synthesized and characterized in this thesis. The hydrophilic blocks were based upon the nucleophilic step polymerization of 3, 3′-disulfonated, 4, 4′-dichlorodiphenyl sulfone (SDCDPS) with an excess 4, 4′-biphenol (BP) to afford phenoxide endgroups. The partially fluorinated hydrophobic blocks were largely based on 4, 4′-hexafluoroisopropylidenediphenol (6F-BPA) and various difluoro monomers (excess). These copolymers were obtained through moderate temperature (~130-150°C) coupling reactions, which minimize the ether-ether interchanges between hydrophobic and hydrophilic telechelic oligomers via a nucleophilic aromatic substitution mechanism. The copolymers were obtained in high molecular weights and were solvent cast into tough membranes, which had nanophase separated hydrophilic and hydrophobic regions. The performance and structure-property relationships of these materials were studied and compared to random copolymer systems. NMR results supported that the multiblock sequence had been achieved. They displayed superior proton conductivity, due to ionic, proton conducting channels formed through the self-assembly of the sulfonated blocks. The nano-phase separated morphologies of the copolymer membranes were studied and confirmed by transmission electron microscopy (TEM) and small angle X-ray scattering (SAXS). Through control of a variety of parameters, including ion exchange capacity and sequence lengths, performances as high, or even higher than those of the state-of-the-art PEM, Nafion®, were achieved. Another series of semi-crystalline hydrophobic poly(ether ether ketone)-hydrophilic sulfonated poly(arylene ether sulfone) (PEEK-BPSH100) multiblock copolymers was first synthesized and characterized. However due to their semi-crystalline structure, PEEK blocks are insoluble in most organic solvents at relatively low reaction temperatures, which prevents the coupling reaction between PEEK and BPS100. In order to facilitate the synthesis and processing, removable bulky ketimine was introduced to synthesize amorphous pre-oligomers poly(ether ether ketimine) (PEEKt). The synthetic procedure first involves the synthesis of hydrophobic poly(ether ether ketimine)-hydrophilic sulfonated poly(arylene ether sulfone) (PEEKt-BPS100) multiblock pre-copolymers via coupling reactions between phenoxide terminated hydrophilic BPS100 and fluorine terminated hydrophobic PEEKt blocks. The membranes cast from PEEKt-BPS100 were boiled in 0.5M sulfuric acid water solution to hydrolyze the amorphous PEEKt blocks to semi-crystalline PEEK blocks and acidify BPS100 blocks to BPSH100 blocks simultaneously. FT-IR spectra clearly showed the successful hydrolysis and acidification. The proton conductivity, water uptake and other membrane properties of the acidified semi-crystalline PEEK-BPSH100 membranes were then evaluated and compared with those of the state-of-the-art PEM, Nafion®. / Ph. D.

semi-crystalline

partially fluorinated

disulfonated poly(arylene ether sulfone)

multiblock copolymers

hydrophobic-hydrophilic

fuel cell

proton exchange membrane

Cellulose Esters and Cellulose Ether Esters for Oral  Drug Delivery Systems

Arca, Hale Cigdem

01 November 2016

Amorphous solid dispersion (ASD) is a popular method to increase drug solubility and consequently poor drug bioavailability. Cellulose ω-carboxyesters were designed and synthesized specifically for ASD preparations in Edgar lab that can meet the ASD expectations such as high Tg, recrystallization prevention and pH-triggered release due to the free -COOH groups. Rifampicin (Rif), Ritonavir (Rit), Efavirenz (Efa), Etravirine (Etra) and Quercetin (Que) cellulose ester ASDs were investigated in order to increase drug solubility, prevent release at low pH and controlled release of the drug at small intestine pH that can improve drug bioavailability, decrease needed drug content and medication price to make it affordable in third world countries, and extent pill efficiency period to improve patient quality of life and adherence to the treatment schedule. The studies were compared with cellulose based commercial polymers to prove the impact of the investigation and potential for the application. Furthermore, the in vitro results obtained were further supported by in vivo studies to prove the significant increase in bioavailability and show the extended release. The need of new cellulose derivatives for ASD applications extended the research area, the design and synthesis of a new class of polymers, alkyl cellulose ω-carboxyesters for ASD formulations investigated and the efficiency of the polymers were summarized to show that they have the anticipated properties. The polymers were synthesized by the reaction of commercial cellulose alkyl ethers with benzyl ester protected, monofunctional hydrocarbon chain acid chlorides, followed by removal of protecting group using palladium hydroxide catalyzed hydrogenolysis to form the alkyl cellulose wcarboxyalkanoate. Having been tested for ASD preparation, it was proven that the polymers were efficient in maintaining the drug in amorphous solid state, release the drug at neutral pH and prevent the recrystallization for hours, as predicted. / Ph. D.

Cellulose esters

cellulose ether esters

Amorphous solid dispersions

structure-property relationship

anti-HIV

rifampicin

quercetin solubility enhancement

Investigation of the Influence of Selected Variables on the Solid State Structure-Property Behavior of Segmented Copolymers

Sheth, Jignesh Pramod

31 January 2005

Segmented copolymers are a commercially important class of materials that are utilized in a wide variety of applications. In these systems a relatively large number of variables such as backbone chemistry, segment molecular weight, and the overall molecular weight of the copolymer can be independently controlled to engineer materials with targeted properties. Such versatility also means that a large number of variables can influence the morphology and therefore, properties and performance of segmented copolymers. In this dissertation, the influence of selected variables on the solid state structure-property behavior of segmented poly(ether-block-amide), polyurethane, polyurethaneurea, and polyurea copolymers is explored. The specific variables which have been utilized singly or in conjunction with others are hard segment crystallizability, crystallization conditions, hard segment content, soft segment type and molecular weight, nature of hydrogen bonding, extent of inter-segmental hydrogen bonding, segment symmetry, and chain architecture. In poly(ether-block-amide)s, it was found that the morphology of both the crystalline and the amorphous phase depend upon the polyamide content of the sample and, as expected, the crystallization conditions. A comparison of polydimethylsiloxane based segmented polyurethanes with their polyurea counterparts demonstrated that for a constant hard segment content the soft segment molecular weight particularly governs the extent of microphase separation in these materials. The nature of hydrogen bonding, monodentate or bidentate, also strongly influences their mechanical response. Remarkably, the polyurea sample with a polydimethylsiloxane molecular weight of 7000 g/mol and a hard segment content of 25 wt % exhibited a remarkable service temperature window (for rubber-like behavior) of ca. 230°C (from -55°C to 175°C) whereas it was ca. 200°C wide (from -55°C to 145°C) for the equivalent polyurethane sample. The extremely high chemical incompatibility between the polydimethylsiloxane of sufficiently high molecular weight and urethane or urea segment is expected to generate a relatively sharp interface between the soft matrix and the dispersed hard domains. Therefore, a polyether co-soft segment was incorporated in a controlled manner along the chain backbone, which resulted in inter-segmental hydrogen bonding between the ether and the urea segments. The consequent segmental mixing gave rise to a gradient interphase, which led to a significant improvement in the tensile strength, and elongation at break in selected polydimethylsiloxane segmented polyurea copolymers. The importance of the hydrogen bonding network in model polyurethaneurea copolymers was also explored by utilizing LiCl as molecular probe. It has been demonstrated that hydrogen bonding plays an important role, over and above microphase separation, in promoting the long-range connectivity of the hard segments and the percolation of the hard phase through the soft matrix. The incorporation of hard segment branching in these polyurethaneurea also reduced the ability of the hard segments to pack effectively and establish long-range connectivity. The disruption of the percolated hard phase resulted in a systematic softening of the copolymers. The role of chain architecture in governing the structure/property/processing of segmented was also investigated by comparing highly branched segmented polyurethaneureas with their linear analogs. These copolymers were based on poly(propylene oxide) or poly(tetramethylene oxide) as the soft segments The highly branched copolymers utilized in this dissertation were able to develop a microphase morphology similar to their linear analogs. Particularly noteworthy, and surprising, was the observation of weak second order interference shoulder in the respective small angle X-ray scattering profiles of the highly branched samples based on poly(propylene oxide) of MW 8200 and 12200, indicating the presence of at least some level of long-range order of the hard domains in these samples. Tapping-mode atomic force microscopy phase images of these two samples clearly confirmed the small angle X-ray scattering results. In addition to the strain induced crystallization of the poly(tetramethylene oxide) MW 2000 g/mol based linear polyurethaneureas, the highly branched analog of this sample also exhibited similar behavior at ambient temperature and uniaxial deformation of ca. 400 % strain. Wide angle X-ray scattering confirmed the above observation. The reduced ability of the branched polymers to entangle resulted in slightly poorer mechanical properties, such as tensile strength, elongation at break, and stress relaxation as compared to their linear analogs. However, primarily due to their reduced entanglement density, the branched polyurethaneureas had significantly lower ambient temperature solution viscosity as compared to their linear polyurethaneurea analogs. Therefore, these highly branched polyurethaneureas can be more easily processed than the latter materials. Finally, it was demonstrated that non-chain extended segmented polyurethane and polyurea copolymers in which the hard segment is based on only a single diisocyanate molecule may well exhibit properties, such as the breadth of the service window, the average plateau modulus, stiffness, tensile strength, and elongation at break that are similar to chain extended segmented copolymers that possess distinctly higher hard segment content. A careful control of the hard segment symmetry and the nature of the hydrogen bonding is necessary to achieve such improved performance in the non-chain extended systems. Therefore, the results of this study provide new direction for the production of thermoplastic segmented copolymers with useful structural properties. / Ph. D.

structure-property behavior

hydrogen bonding

polyurethane

poly(ether-block-amide)

microphase separation

segmented copolymer

atomic force microscopy

Shock Tube Ignition Studies of Renewable Diesel Fuels for Medium and Heavy-Duty Transportation

Mohammed, Zuhayr Pasha

01 January 2024

Currently extensive research on alternative fuels is being conducted due to their increasing demand to reduce greenhouse emissions. One renewable fuel studied in this work is dimethyl ether (DME) blended with propane(C3H8) as a potential mixture for heavy-duty engines used in semi-trucks. The blend has the potential to drastically reduce particulate and greenhouse gas emissions compared to a conventional diesel engine operating under similar conditions. To develop the use of mixture, one must conduct detailed conceptual and simulation studies before progressing to detail studies in CFD, engine modifications, and live testing. For simulations, accurate high-fidelity chemical kinetic models are necessary. However, the validity of the chemical kinetic mechanism for operating conditions of a heavy-duty mixing-controlled compression (MCCI) engine was widely unknown until recent work presented here and published. In this work, we studied the ignition of DME and propane blends in a shock tube under MCCI engine conditions. Ignition delay time (IDT) gathered behind the reflected shock for DME-propane mixtures for heavy-duty compression ignition (CI) engine parameters. Testing was conducted for undiluted varieties spanning from temperatures of 700 to 1100 K at pressures ranging from 55 to 84 bar for various blends (100% CH3OCH3, 100% C3H8, 60% CH3OCH3/ 40% C3H8) of DME and propane were combusted in synthetic air (21% O2/ 79% N2). Several experiments were conducted at higher pressures (90-120 bar) to improve the model performance and accuracy. The ignition delay times (IDTs) were compared to recent mechanisms, including Aramco3.0, NUIG, and Dames et al. A common trend among the mechanisms was overpredicted experimental IDTs. Further studies were conducted by a sensitivity analysis using the Dames et al. model, and critical reactions sensitive to IDTs of DME-propane mixture near 60 bar are outlined. Chemical analysis was conducted on the NTC region to explain chemical kinetics which is critical for developing MCCI heavy duty engines.

Dimethyl Ether (DME)

propane

Shocktube

Alternative Fuel

Biofuel

High Pressures

Heavy-duty engines

Mechanical Engineering

Anionic Phospho-Fries Rearrangements for the Synthesis of Planar-Chiral Ferrocenes and their Application in (atropselective) Suzuki-Miyaura Reactions / Anionische Phospho-Fries Umlagerungen zur Synthese Planar-Chiraler Ferrocene und deren Anwendung in (Atropselektiven) Suzuki-Miyaura Reaktionen

Korb, Marcus

25 September 2017

The present PhD thesis describes the synthesis and characterization of novel planarchiral 1,2-P,O-ferrocenes and their application in the Pd-catalyzed Suzuki-Miyaura reaction. It was especially focused on the development of a new synthetic pathway to this type of substitution pattern by applying the anionic phospho-Fries rearrangement in ferrocene chemistry. Starting from hydroxy ferrocene, a high diversity of Fc–O–P- type (Fc = (n5-C5H5)(n5-C5H4)) compounds were synthesized, whereby the electronic properties of the phosphorus fragments were varied. The anionic phospho-Fries rearrangement successfully occurred subsequent to an ortho-lithiation with a non-nucleophilic base giving the 1,2-P,O-ferrocenes in up to quantitative yields. The usage of chiral pool-based alcohols for the synthesis of chiral ferrocenyl phosphates allowed a diastereoselective proceeding, giving single isomers in up to 95% de. Temperature-dependent investigations of mixed ferrocenyl-, phenyl- and Nheterocyclicphosphates revealed a limitation of ferrocenyl-based rearrangements per reaction step, contrary to phenyls. 1,2-P,O-ferrocenyl phosphonates could successfully be converted into phosphines by applying Stelzer P,C cross-coupling reactions on ferrocenes for the first time. Their usage as ligands for C,C cross-coupling reactions was confirmed by the synthesis of sterically hindered biaryls in high yields at 70°C with a low catalyst loading of 1 mol-% Pd. Functionalization of the 1,2-P,O -structural motif could be achieved by applying nucleophilic aromatic substitution reactions (SNAr) as an alternative pathway for the synthesis of ferrocenyl aryl ethers. Subsequent to a Fries rearrangement sterically-demanding 1,3-di-orthosubstituted aryloxy ferrocenes could be obtained. Multi SNAr reactions of hydroxyferrocenes at polyfluorinated arenes gave up to pentaferrocenyl-functionalized aryl ethers, whose electrochemical properties were investigated. The reaction of CH2-enlarged ferrocenylmethanols gave α-ferrocenylcarbenium ions instead of phosphates, while treating them with chlorophosphates. Enantiopure 2-P(S)Ph2-substituted derivatives of these ions underwent a subsequent intermolecular “S2−“ migration, resulting in thioethers, for example (Sp,Sp)-(2-(P(S)Ph2)FcCH2)2S, in a unique mechanism. Instead, the presence of electronrich arenes gave electrophilic aromatic substituted benzenes bearing chiral ferrocenylmethyl backbones. These type of ligands gave biaryls with up to 26 % ee. / Die vorliegende Arbeit beschäftigt sich mit der Synthese und Charakterisierung von neuartigen planar-chiralen 1,2-P,O-ferrocenen sowie deren Anwendung in der Pd-katalysierten Suzuki-Miyaura Reaktion. Dabei lag der Focus in der Anwendung anionischer phospho-Fries Verschiebungen auf Ferrocene um dieses spezielle Substitutionsmuster erhalten zu können. Ausgehend von Hydroxyferrocenen wurde so eine Vielzahl neuer Verbindungen des Typs Fc–O–P (Fc = (n5-C5H5)(n5-C5H4)) synthetisiert, wobei die elektronischen Eigenschaften des Phosphor-tragenden Fragmentes variiert wurden. Die anionische phospho-Fries Verschiebung erfolgte im Anschluss einer ortho-Lithiierung mit einer nicht-nucleophilen Base, was 1,2-P,O-Ferrocene nahezu quantitative ergab. Durch die Verwendung von chiral-pool basierten Alkoholen für die Synthese chiraler Ferrocenylphosphate konnte eine diastereoselective 1,3-O->C Umlagerung mit Isomerenreinheiten von bis zu 95 % erreicht werden. Untersuchungen von gemischten Ferrocenyl-, Phenyl- und N-heterocyclischen Phosphaten bei verschiedenen Temperaturen zeigte eine Limitierung Ferrocenyl-basierter Umlagerungen pro Reaktionsschritt im Gegensatz zu denen von Phenylen. Die erhaltenen 1,2-P,O-Ferrocenylphosphate wurden erstmals mittels Stelzer P,C Kreuz-Kupplungsreaktionen erfolgreich in Phosphane umgesetzt. Deren Verwendung als Ligand in C,C Kreuz-Kupplungsreaktionen wurde am Beispiel der Synthese räumlich anspruchsvoller Biaryle in hohen Ausbeuten bei nur 70°C und niedrigen Katalysatorbeladungen von 1 mol-% Pd demonstriert. Die Funktionalisierung des 1,2-P,O-Strukturmotifes konnte durch die Anwendung von nucleophilen aromatischen Substitutionsreaktionen erreicht werden, die einen alternativen Zugang zu Ferrocenylarylethern bietet. Im Anschluss an eine Fries Umlagerung konnten so sterisch anspruchsvolle 1,3-di-ortho-substituierte Ferrocenylarylether erhalten werden. Durch mehrfache SNAr Reaktionen von Hydroxyferrocenen an polyfluorierten Aromaten wurden bis zu fünf-fach substituierte Ether erhalten, deren elektrochemischen Eigenschaften untersucht wurden. Die um eine CH2-Einheit verlängerten Ferrocenylmethanole gaben bei Reaktion mit Chlorophosphaten alpha Ferrocenylcarbeniumionen anstelle der gewünschten Phosphate. Enantiomerenreine 2-P(S)Ph2-substituierte Derivate dieser Ionen durchliefen anschließend einen intermolekularen ”S2–“ Transfer in einem einzigartigen Mechanismus, was bspw. in Thioethern des Typs (Sp,Sp)-(2-(P(S)Ph2)FcCH2)2S resultierte. In Anwesenheit elektronenreicher Aromaten wurden elektrophile aromatischen Substitutuionen und die Bildung chiraler ferrocenylmethyl-substitutuierter Benzene beobachtet. Deren Einsatz als Ligand ergab Biaryle mit bis zu 26 % ee.

Ferrocen

Planare Chiralität

Fries Umlagerung

Suzuki-Miyaura Reaktion

Chiral Pool

Phosphat

Phosphonat

Phosphin

Biaryl Synthese

Elektrochemie

Röntgen Einkristall- Strukturanalyse

Ether Bildung

Ferrocene

Planar Chirality

Fries Rearrangement

Suzuki-Miyaura Reaction

Chiral Pool

Phosphate

Phosphonate

Phosphine

Biaryl Coupling

Electrochemistry

Ether Formation

ddc:540

Ferrocen

Fries

Umlagerung

Katalyse

Phosphate

Phosphin

Elektrochemie

Einkristall

Strukturanalyse

Ether