Highly-ordered onion micelles made from amphiphilic highly-branched copolymers

Canning, S.L., Ferner, J.M.F., Mangham, N.M., Wear, T.J., Reynolds, S.W., Morgan, J., Fairclough, J.P.A., King, S.M., Swift, Thomas, Geoghegan, M., Rimmer, Stephen

12 November 2018

Yes / Uniform onion micelles formed from up to ten nano-structured polymer layers were produced by the aqueous self-assembly of highly-branched copolymers. Highly-branched poly(alkyl methacrylate)s were chain extended with poly(acrylic acid) in a two-step reversible addition–fragmentation chain transfer-self-condensing vinyl polymerization (RAFT-SCVP) in solution. The resulting polymers were dispersed into water from oxolane (THF) using a self-organized precipitation-like method and the self-assembled particles were studied by phase-analysis light scattering, small-angle neutron scattering, and electron microscopy techniques. The relative hydrophobicity of the blocks was varied by changing the alkyl methacrylate (methyl, butyl, or lauryl) and this was found to affect the morphology of the particles. Only the poly(butyl methacrylate)-containing macromolecule formed an onion micelle structure. The formation of this morphology was observed to depend on: the evaporation of the good solvent (THF) during the self assembly process causing kinetic trapping of structures; the pH of the aqueous phase; and also on the ratio of hydrophobic to hydrophilic segments within the copolymer. The lamellar structure could be removed by annealing the dispersion above the glass transition temperature of the poly(butyl methacrylate). To exemplify how these onion micelles can be used to encapsulate and release an active compound, a dye, rhodamine B (Rh B), was encapsulated and released. The release behaviour was dependent on the morphology of the particles. Particles formed containing the poly(methyl methacrylate) or poly (lauryl methacrylate) core did not form onions and although these materials absorbed Rh B, it was continuously released at room temperature. On the other hand, the lamellar structure formed from branchpoly( butyl methacrylate)-[poly(butyl methacrylate)-block-poly(acrylic acid)] allowed for encapsulation of approximately 45% of the dye, without release, until heating disrupted the lamellar structure. / EPSRC and Domino UK Ltd for a Nanotechnology KTN CASE studentship to support SLC, Experiments at the ISIS Pulsed Neutron and Muon Source were supported by a beam time allocation from the Science and Technology Facilities Council (experiment numbers RB1220108 and RB1320167).

Onion micelles

Linear block copolymers,

Copolymers

Synthesis and characterization of oxazoline homopolymers, random and block copolymers

Cai, Gangfeng

January 1991

No description available.

Chemistry, Polymer

oxazoline homopolymers block copolymers

Conjugation of Proteins with PEO-PPO Block Copolymers

Clark-Mizer, Emma

26 July 2022

No description available.

Chemical Engineering

Pluronics

Bioconjugates

Block Copolymers

Conjugation

Polysiloxane-polyarylester block copolymers: synthesis and characterization

Brandt, Patricia J. Andolino

January 1986

Passive damping has been defined as a key element in vibration control. It is believed that the approach to passive damping could be addressed through the use of carefully designed viscoelastic polymeric materials. This dissertation describes the synthesis and characterization of multiphase, transparent block copolymers that are potential candidates for passive damping applications in large space structures. Relatively high molecular weight polysiloxane-polyarylester block copolymers were prepared by two different synthetic routes. A solution technique was used to synthesize well-defined, perfectly alternating block copolymers by reacting a difunctional silylamine—terminated siloxane oligomer with a difunctional hydroxyl-terminated polyarylester oligomer. A second approach involved the preparation of a segmented (or random) block copolymer by an interfacial, phase—transfer technique in which various polyarylester block lengths are formed <u>during</u> the copolymerization by reacting bisphenol-A, terephthaloyl chloride, and isophthaloyl chloride with a difunctional aminopropyl-terminated siloxane oligomer. To vary the miscibility of the siloxane and ester phases, and in turn the physical properties of the block copolymers, the block molecular weights and the siloxane block compositions (dimethyl, dimethyl-diphenyl, or dimethyl-trifluoropropylmethyl) were controlled. Structure analysis by NMR (proton and silicon) and FTIR verified that the desired starting oligomers and block copolymers were successfully prepared. Intrinsic viscosity measurements, size exclusion chromatography, and the fact that tough transparent films could be solution cast and compression molded indicated that relatively high molecular weight materials were prepared. Due to the high degree of incompatibility of the "soft" siloxane segments and the "hard" ester segments in the block polymers, a two-phase microstructure developed at relatively low block molecular weights. In addition to microphase separation, partial phase mixing was apparent from thermal, mechanical, and microscopic characterization techniques. Compared to a polyarylester homopolymer, the siloxane modified polyarylester block polymers displayed improved resistance to atomic oxygen degradation as seen from x-ray photoelectron spectroscopy and scanning electron microscopy. All physical properties were found to be dependent upon siloxane block composition and copolymer block molecular weights. In conclusion, new siloxane-ester block copolymers were prepared and characterized. They are believed to be potentially useful materials for passive damping applications in the space environment. / Ph. D. / incomplete_metadata

LD5655.V856 1986.B724

Block copolymers

Block Copolymer-derived Porous Polyimides and Carbon for High-Performance Energy Storage

Guo, Dong

12 May 2022

Block copolymer-derived nanoporous materials are featured with microstructures defined by the microphase separation of constituent blocks, enabling various applications in energy storage. Dictated by the molecular weights and volume fractions of constituent blocks, the microphase separation forms nanoscale microstructures of 1-100 nm. Selective removal of a sacrificial phase produces nanopores with tailored pore width, continuity, and tortuosity. The remaining phase customizes the properties of resulting nanoporous materials, including specific surface area, electrical conductivity/insulation, and mechanical performance. Therefore, block copolymer-derived porous materials are felicitous for use in high-performance energy storage. This dissertation presents the utilization of block copolymers to derive nanoporous materials: i) high-modulus polyimide separators for lithium-metal batteries, and ii) high-surface-area carbon electrodes for fast-charging zinc-ion batteries. In lithium-metal batteries, the dendritic growth of lithium leads to deteriorating performance and severe safety concerns. Suppressing lithium dendrites is imperative to guarantee both high performance and safe cycling. Mesoporous polyimide separators are promising for dendrite suppression: i) the mesopores are smaller than the width of lithium dendrites, preventing lithium dendrites from penetrating the separator. ii) The high-modulus polyimide ceases the growth of lithium dendrites. Herein, this dissertation reports a mesoporous polyimide separator produced by thermalizing polylactide-b-polyimide-b-polylactide at 280 °C. The mesoporous polyimide separator exhibits a median pore width of 21 nm and a storage modulus of 1.8 GPa. When serving as a dendrite-suppressing separator in lithium-metal batteries, the mesoporous polyimide separator enables safe cycling for 500 hours at a current density of 4 mA/cm2. In zinc-ion batteries, developing cathodes compatible with fast charging remains a challenge. Conventional MnO2 gravel cathodes suffer from low electrical conductivity and slow ion (de-)insertion, resulting in poor recharging performance. In this dissertation, porous carbon fiber (PCF) supported MnO2 (PCF@MnO2), comprising nanometer-thick MnO2 deposited on block copolymer-derived PCF, serves as a fast-charging cathode. The high electrical conductivity of PCF and fast ion (de-)insertion in nanometer-thick MnO2 both contribute to a high rate capability. The PCF@MnO2 cathode, with a MnO2 loading of 59.1 wt%, achieves a MnO2-based specific capacity of 326 and 184 mAh/g at a current density of 0.1 and 1.0 A/g, respectively. This dissertation investigates approaches to utilizing block copolymers-derived nanoporous materials for high-performance energy storage. Those approaches are envisaged to inspire the design of block copolymer-derived nanoporous materials, and advance the development of "beyond Li-ion" energy storage. / Doctor of Philosophy / When we talk with friends on mobile phones, accomplish works on laptops, drive back home and see family's smiling faces under lamplights, we must have noticed that our daily life significantly relies on electrical energy. Although being predominantly employed in today's rechargeable energy storage, lithium-ion batteries using graphite anodes have approached their theoretical energy limits. We are expecting better-performance batteries for a more convenient life: to fully charge our phones faster, to use our laptops for a longer time, and to drive our electric cars for a further distance. Lithium-metal batteries and aqueous zinc-ion batteries stand out for "beyond lithium-ion" energy storage because they deliver more energy and charge faster. The commercialization of lithium-metal batteries and zinc-ion batteries may benefit from revolutionary porous materials derived from block copolymers. On one hand, lithium-metal batteries employ metallic lithium anodes, storing about 10 times of energy compared to equal-weight graphite anodes and allowing faster charging rates. However, the lithium-metal anodes grow needle-shaped dendrites during cycling. Those lithium dendrites traverse the battery separator through its large pores, causing internal short circuits and even fire hazards. Suppressing lithium dendrites is imperative for safe lithium-metal batteries. Stiff separators with small pores can suppress lithium dendrites. The small pores prevent lithium dendrites from traversing, and the stiff separators cease the dendritic growth. This dissertation introduces a dendrite-suppressing separator derived from block copolymers comprising stiff polyimide blocks and vulnerable blocks. When those block copolymers form films, the vulnerable blocks spontaneously disperse as a network embedded in the polyimide. Then, the vulnerable blocks are removed at elevated temperatures to create interconnected small pores. This porous polyimide separator suppresses lithium dendrites to allow safe cycling for 500 hours, surpassing today's separators which encounter short circuits within 60 hours. On the other hand, zinc-ion batteries require fast-charging cathodes for high charging rates. A fast-charging cathode demands both good electrical conductivity and fast ion insertion. Herein, this dissertation reports a porous carbon fiber supported MnO2 cathode. The block copolymers comprise a polyacrylonitrile block and a vulnerable block. The vulnerable blocks form a network dispersing in the polyacrylonitrile fibers. At elevated temperatures, polyacrylonitrile is converted to graphitic carbon fibers, and the vulnerable network decomposes to create interconnected pores. The porous carbon fibers afford a large surface area, allowing a high loading of MnO2 to deposit as nanometer-thick sheaths. The resulting cathode combines good electrical conductivity of porous carbon fibers and the fast ion insertion in thin MnO2 sheaths, therefore, exhibiting superior fast-charging performance. This dissertation reports the methods of using block copolymers to produce porous materials for high-performance batteries. We envisage those methods to inspire the design of block copolymer-derived porous materials, and advance the development of high-performance energy storage for a more convenient life.

Block copolymers

porous materials

energy storage

Synthesis and Characterization of Complex Polymer Topologies using Ring-Opening Metathesis Polymerization

Alaboalirat, Mohammed Ali

09 August 2022

Bottlebrush polymers are intriguing topologies that have become more significant in various applications, including drug delivery, elastomers, photonic crystals, anti-fouling coatings, nanoporous materials, and electronic and transport substrates. Polymeric side chains are tightly grafted to a polymer backbone in these macromolecules. Bottlebrush polymers' densely bonded structure causes steric repulsion between nearby polymer chains, leading them to exhibit a chain-extended conformation. Even though these extraordinary macromolecules have several uses, the transformational promise of the bottlebrush polymer architecture has yet to be realized due to the difficulty in synthesizing large molecular weight bottlebrush polymers. This dissertation illustrates the ability of the optimized grafting-through strategy to create controlled supramolecular polymeric networks (SPNs) and different types of topologies, including block copolymers and tapered bottlebrush polymers. We show that the optimized synthesis of bottlebrush polymers using a direct-growth approach results in a controlled product and monomodal size exclusion chromatography (SEC) peaks. The optimization of the direct-growth approach depends on two factors: monomer type and percentage of monomer to polymer conversion in the reversible-deactivation radical polymerization (RDRP) step. Moreover, performing ring-opening metathesis polymerization (ROMP) initiated by Grubbs 3rd generation catalyst (G3) on a norbornene functionalized macromolecules allows for creating polymers with bulky side chains. This strategy was implemented to create methylated, acetylated, and native poly(β-cyclodextrin) that reached a degree of polymerization of 150 and molecular weights > 150 kg/mol. These results were 10-fold higher than the reported method using atom transfer radical polymerization (ATRP) with β-cyclodextrin functionalized with methacrylate group. Furthermore, multiple macromonomers were prepared using ATRP and photoiniferter polymerization that are functionalized with norbornene. These macromonomers were used in the following ROMP reaction to result in multiple series of amphiphilic bottlebrush block copolymers and tapered bottlebrush polymers. The surface tension measurements on the self-assembled amphiphilic bottlebrush block copolymer series in water revealed an ultralow critical micelle concentration (CMC), 1-2 orders of magnitude lower than its linear counterpart. Combined with coarse-grained molecular dynamics simulations, fitting small-angle neutron scattering traces (SANS) allowed us to evaluate solution conformations of micellar nanostructures for self-assembled macromolecules. Furthermore, the tapered bottlebrush polymer series SANS traces were collected to investigate their molecular arrangement in dilute solution. For the first time, summation scattering models describing both bottlebrush polymer shape and side chain polymer conformations were utilized. Using these models, we extracted physical parameters of the polymers, including bottlebrush radius and length as well as side chain excluded volume parameter and correlation length. / Doctor of Philosophy / Bottlebrush polymers are intriguing topologies that have become more significant in a variety of applications, including photonic crystals and nanoporous materials. In these macromolecules, polymeric side chains are densely grafted to a polymer backbone which causes steric repulsion between nearby polymer chains. However, even though these extraordinary macromolecules have several uses, the transformational promise of the bottlebrush polymer architecture has yet to be realized due to the difficulty in synthesizing large molecular weight bottlebrush polymers. This dissertation illustrates the ability of the optimized grafting-through strategy to create controlled supramolecular polymeric networks (SPNs) and different types of topologies, including block copolymers and tapered bottlebrush polymers. This dissertation shows that the optimized synthesis of bottlebrush polymers using direct-growth approach results in a controlled synthesis. The optimization of the direct-growth approach depends on two factors: monomer type and percentage of monomer to polymer conversion in creating the macromonomer step. In addition, performing ring-opening metathesis polymerization (ROMP) initiated by Grubbs 3rd generation catalyst on a norbornene functionalized macromolecules allows for creating polymers with bulky side chains. This strategy was implemented to create methylated, acetylated, and native poly(β-cyclodextrin) that reached a degree of polymerization of 150 and molecular weights > 150 kg/mol. Multiple macromonomers were prepared using ATRP and photoiniferter polymerization that are functionalized with norbornene. These macromonomers were used in the following ROMP reaction to result in multiple series of amphiphilic bottlebrush block copolymers and tapered bottlebrush polymers. The surface tension measurements on the self-assembled amphiphilic bottlebrush block copolymer series in water revealed an ultralow critical micelle concentration (CMC). In addition, fitting of small-angle neutron scattering traces (SANS) allowed us to evaluate solution conformations for micellar nanostructures for self-assembled macromolecules. Furthermore, the tapered bottlebrush polymer series SANS traces were collected to investigate their molecular arrangement in dilute solution. Finally, for the first time, models were used to extract physical parameters of the polymers, including bottlebrush radius and length as well as side chain excluded volume parameter and correlation length.

Bottlebrush Polymer

Supramolecular Polymeric Networks

Block Copolymers

Multiphase star-like copolymers containing lignin: synthesis, properties and applications

Oliveira, Willer de

28 July 2008

Multiphase star-like copolymers containing lignin have been synthesized and characterized. All copolymers contained hydroxypropyl lignin (HPL) as the central core. Polycaprolactone (PCL), cellulose propionate (CP) or polystyrene (PS), served as radiating blocks attached to the lignin core in star-like manner. These materials were studied in relation to their structure, morphology, effect on crystallization behavior and application in polymer blends. Three series of semi-crystalline (PCL)_n — HPL have been synthesized with HPL segments of 2,100, 3,500 and 6,400 molecular weight, respectively, and polycaprolactone blocks of varying size. Copolymers were produced by either copolymerizing ɛ-caprolactone or grafting preformed PCL segments onto HPL. The thermal and optical properties of these copolymers were investigated by DSC, DMTA and optical microscopy. The copolymers exhibited variable thermal behavior in relation to composition. The crystallization of PCL blocks was mainly governed by the nature of the HPL phase. PCL block length was another variable that affected crystallinity. The longer the segment, the higher the degree of crystallinity. The compatibility, morphology and mechanical properties of (PCL)_n - HPL copolymers blended with poly(vinyl chloride) were also investigated. Methods used in this study included DSC, DMTA, SEM, TEM and stress-strain testing. The blends were shown to be compatible in all proportions. Mono-hydroxyl terminated cellulose propionate oligomers were synthesized by degradation with hydrogen bromide of a fully substituted, high molecular weight cellulose propionate molecule. Evidence of strict monofunctionality was demonstrated by H-NMR spectroscopy. Thermal analysis results indicated that the oligomers were semi-crystalline and their melting points were functions of molecular weight. (CP)_n — HPL copolymers were synthesized by grafting oligomeric CP segments onto HPL via a coupling agent. The thermal and morphological properties of the copolymers were characterized by DMTA, DSC and TEM. Analysis by thermal methods and by electron microscopy showed strong evidence for microphase separation between HPL and CP segments. Cellulose propionate chains crystallize even at a low degree of polymerization, such as DP 5. The copolymer morphologies exhibit a broad variety of features. They vary from dispersed fibrils to spheres like and alternate lamella type patterns according to composition and molecular weights. The interfacial activity of the copolymers in blends of CP and HPL prepared in the melt state was also investigated. The tensile properties of the ternary blends were altered slightly by the presence of the copolymer. Melt blended cellulose propionate and HPL with low degree of propoxylation forms a miscible system with up to 40% HPL component. The incorporation of 5% of the (CP)_n — HPL copolymer reduces the tensile strength by about 10%. Thermal behavior of melt blended cellulose propionate and HPL with high degree of propoxylation indicates the formation of an incompatible system at any composition. Before the addition of the copolymer the blend exhibits higher toughness, elongation up to 160%, and a Young's modulus of 23 ksi. The copolymer-modified blend shows a decrease in toughness and an increase in tensile strength by about 10%. The synthesis and characterization of (PS)_n — HPL copolymers was accomplished in an analogous manner. When added to blends of PS and HPL, (PS)_n -- HPL produced improved mechanical properties of the blends. Scanning electron microscopy of fracture surfaces demonstrated that the addition of copolymer to the PS/HPL blends improved the adhesion of the two phases. The addition of (PS)_n — HPL copolymer to the 90 PS/10 HPL blend system strongly reduced, by about 10 fold, the particle size of the unmodified blend. No significant difference was observed in the morphology of the 80 PS/20 HPL system. The phases exhibited poor adhesion before and after the addition of copolymer. / Ph. D.

LD5655.V856 1991.O448

Block copolymers

Lignin

Liquid crystalline multi-block copolymers

Cooper, Kevin L.

22 May 2007

Lyotropic and thermotropic high strength liquid crystalline polymers have become an important area of research and development in polymeric, high performance materials. These materials have afforded excellent high temperature stability and high strength in the oriented direction, but not in the transverse direction. Hence, "balancing" the properties in both directions is an important area of research. Segmented polymers composed of an amorphous, glassy engineering thermoplastic, and an anisotropic, liquid crystalline polymer were synthesized and investigated. The isotropic phase is based upon a ductile poly(arylene ether sulfone), while the anisotropic segment is based on a rigid poly(arylate) moiety. The difunctionally terminated, controlled molecular weight poly(sulfone) oligomers were synthesized via a nucleophilic aromatic substitution reaction. Functional end groups included phenolic, acetate and carboxyl. The structure and reactivity of these oligomers was characterized by analytical techniques, including FT-IR, NMR, and polymer physical characterization methods such as, differential scanning calorimetry (DSC), thermal gravimetric analysis (TGA), and thermal mechanical analysis (TMA), and dynamic mechanical thermal analysis (DMTA). The well characterized, difunctionally terminated poly(sulfone) oligomers were then utilized along with ester forming monomers in a subsequent melt acidolysis reaction to form segmented poly(sulfone)-poly(arylate) co- or terpolymers. Earlier work by Lambert (281-283) showed that solution and interfacial techniques could only be utilized to synthesize segmented polymers with low poly(arylate) contents. The melt acidolysis technique allowed the synthesis of poly(sulfone)- poly(arylate) polymers with poly(arylate) contents as high as 90 weight percent. Along with a high degree of agitation, the melt acidolysis technique utilized chlorobenzene as a solvent in the initial stage of the reaction to enhance the mixing of the poly(sulfone) oligomers and ester forming monomers, allowing true segmented polymers to be formed. This was proven by FT-IR and extraction studies, which determined that very little of the original poly(sulfone) oligomer was extracted by refluxing chloroform. The morphology of these polymers was studied by polarized optical microscopy, and wide angle X-ray scattering. Low weight fraction poly(arylate) co- and terpolymers were determined to be amorphous, while higher poly(arylate) weight fraction polymers (15 weight percent or greater) were found to be semi-crystalline or liquid crystalline. Thermal analysis (DSC) also gave evidence that these materials were semi-crystalline or liquid crystalline. Also, as the weight fraction of poly(arylate) was increased, a significant improvement in solvent resistance was observed as well as an improvement in the modulus and tensile strength. / Ph. D.

LD5655.V856 1991.C666

Block copolymers

Novel Approaches To The Synthesis of Clicked Block Copolymers

Flack, Matthew Alexander

16 January 2011

Block copolymers are widely used in both the academic and industrial communities due to their unique properties. With the development of living polymerization techniques, the synthesis of block copolymers with controlled molecular weights and unique architectures has reached an all time high. Here a novel approach to the synthesis of block copolymers, namely polystyrene-b-polyisoprene, using azide-alkyne click chemistry techniques is investigated. Both azido and alkyne-terminated polystyrene were synthesized using ATRP. Azido-terminated polystyrene was synthesized via a substitution reaction between NaN3 and bromo-terminated polystyrene. Alkyne-functionalized polystyrene was synthesized using propargyl 2-bromoisobutyrate as a functional initiator. ¹H NMR and SEC were used to analyze the degree of polymer functionalization. Anionic polymerization techniques were used to synthesize polyisoprene. Polyisoprenyl lithium was reacted with propylene oxide to obtain hydroxyl-terminated polyisoprene. Functionalization of ≥ 90% was demonstrated via flash column chromatography. The aforementioned hydroxyl-terminated polyisoprene was reacted with both 11-chloroundecanoyl bromide and 11-chloroundecanoyl chloride to synthesize halogen-terminated polyisoprene. As with polystyrene, a substitution reaction with NaN3 afforded azido-terminated polyisoprene. Alkyne-functionalized polystyrene was coupled with azido-terminated polyisoprene via click chemistry to create said block copolymers. The reactions were investigated using ¹H and ¹³C NMR, SEC, IR and in some cases TEM. The clicked block copolymers should provide precedent for the synthesis of supramolecular block copolymers. / Master of Science

Click chemistry

Polystyrene

Polyisoprene

Block copolymers

Fundamental adhesive studies of block copolymers

Sheridan, Margaret Mary

January 1985

Models of multiple component, multiple phase adhesives were developed to examine the conflicting demands placed on modern adhesion technology. Styrene and isoprene based block copolymers were investigated 511 order to understand their adhesive properties. The structure of the microphase separated morphology of the materials studied was found to influence the adhesive behavior in applications as hot melt/structural type adhesives and as pressure sensitive adhesives. The thermal and the dynamic mechanical behavior of linear styrene/isoprene/styrene triblock copolymers (40% and 50% by weight styrene) was determined for free films and for films bonding together two rigid adherends. Damping phenomena indicated a broader mechanical relaxation spectrum occurring at higher i temperatures in the bonded assemblies. Microphase separation in the melts of these triblock materials was interpreted as contributing to the formation of residual stresses in both free films and bonded joints under appropriate thermal and pressure histories, illustrating the importance of sample preparation. in the evaluation of multiple phase adhesive systems. / Ph. D. / incomplete_metadata

LD5655.V856 1985.S537

Block copolymers

Adhesives