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Synthese und Charakterisierung von PolyampholytenSchäffner, Friederike Charlotte January 2009 (has links)
Zugl.: Clausthal, Techn. Univ., Diss., 2009
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A Grand Canonical Monte Carlo Molecular Study of a Weak PolyampholyteJimenez, Arturo Martinez 05 1900 (has links)
Over the last few decades, there has been an increasing interest in the study of charged polymers for applications such as desalination of water, flocculation, sewage treatment, and enhanced oil recovery. Polyelectrolyte chains containing both positively and negatively charged units (polyampholytes) have been recently studied as viscosity-control agents in enhanced oil recovery, and as entrapping macromolecules for protection and delayed release of enzymes in hydraulic fracturing. In this study we performed Monte Carlo molecular simulations in a grand canonical ensemble to study the behavior of a weak polyampholyte in a dilute regime. Weak polyampholytes have the ability to dissociate in a limited pH, which makes them interesting for applications that require a pH-triggerable response. The titration behaviors of diblock and random polyampholytes are simulated as a function of solvent quality, electrostatic strength, and salt concentration. For diblock polyampholyte chains in hydrophobic solvents, transition between tadpole-like and globule conformation occurs with variations in the solution pH. Random polyampholytes present extended, globule, and pearl-necklace conformations at different solvent conditions and pH values. At high ionic strength, electrostatic interactions in the polyampholytes become screened and the chains are mostly in globule state.
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Novel Cellulose Nanoparticles for Potential Cosmetic and Pharmaceutical ApplicationsDhar, Neha January 2010 (has links)
Cellulose is one of the most abundant biopolymers found in nature. Cellulose based derivatives have a number of advantages including recyclability, reproducibility, biocompatibility, biodegradability, cost effectiveness and availability in a wide variety of forms. Due to the benefits of cellulose based systems, this research study was aimed at developing novel cellulosic nanoparticles with potential pharmaceutical and personal care applications. Two different cellulosic systems were evaluated, each with its own benefits and proposed applications.
The first project involves the synthesis and characterization of polyampholyte nanoparticles composed of chitosan and carboxymethyl cellulose (CMC), a cellulosic ether. EDC carbodiimide chemistry and inverse microemulsion technique was used to produce crosslinked nanoparticles. Chitosan and carboxymethyl cellulose provide amine and carboxylic acid functionality to the nanoparticles thereby making them pH responsive. Chitosan and carboxymethyl cellulose also make the nanoparticles biodegradable and biocompatible, making them suitable candidates for pharmaceutical applications. The synthesis was then extended to chitosan and modified methyl cellulose microgel system. The prime reason for using methyl cellulose was to introduce thermo-responsive characteristics to the microgel system. Methyl cellulose was modified by carboxymethylation to introduce carboxylic acid functionality, and the chitosan-modified methyl cellulose microgel system was found to be pH as well as temperature responsive.
Several techniques were used to characterize the two microgel systems, for e.g. potentiometric and conductometric titrations, dynamic light scattering and zeta potential measurements. FTIR along with potentiometric and conductometric titration was used to confirm the carboxymethylation of methyl cellulose. For both systems, polyampholytic behaviour was observed in a pH range of 4-9. The microgels showed swelling at low and high pH values and deswelling at isoelectric point (IEP). Zeta potential values confirmed the presence of positive charges on the microgel at low pH, negative charges at high pH and neutral charge at the IEP. For chitosan-modified methyl cellulose microgel system, temperature dependent behaviour was observed with dynamic light scattering.
The second research project involved the study of binding interaction between nanocrystalline cellulose (NCC) and an oppositely charged surfactant tetradecyl trimethyl ammonium bromide (TTAB). NCC is a crystalline form of cellulose obtained from natural sources like wood, cotton or animal sources. These rodlike nanocrystals prepared by acid hydrolysis of native cellulose possess negatively charged surface. The interaction between negatively charged NCC and cationic TTAB surfactant was examined and it was observed that in the presence of TTAB, aqueous suspensions of NCC became unstable and phase separated. A study of this kind is imperative since NCC suspensions are proposed to be used in personal care applications (such as shampoos and conditioners) which also consist of surfactant formulations. Therefore, NCC suspensions would not be useful for applications that employ an oppositely charged surfactant. In order to prevent destabilization, poly (ethylene glycol) methacrylate (PEGMA) chains were grafted on the NCC surface to prevent the phase separation in presence of a cationic surfactant. Grafting was carried out using the free radical approach.
The NCC-TTAB polymer surfactant interactions were studied via isothermal titration calorimetry (ITC), surface tensiometry, conductivity measurements, phase separation and zeta potential measurements. The major forces involve in these systems are electrostatic and hydrophobic interactions. ITC and surface tension results confirmed two kinds of interactions: (i) electrostatically driven NCC-TTAB complexes formed in the bulk and at the interface and (ii) hydrophobically driven TTAB micellization on the NCC rods. Conductivity and surface tension results confirmed that the critical micelle concentration of TTAB (CMCTTAB) shifted to higher values in the presence of NCC. Phase separation measurements allowed us to identify the formation of large aggregates or hydrophobic flocs depending on the TTAB concentration. Formation of NCC-TTAB complexes in aqueous solutions was confirmed by a charge reversal from negative to positive charge on the NCC rods. The effect of electrolyte in shielding the negative charges on the NCC was observed from ITC, surface tensiometry and phase separation experiments. Several mechanisms have been proposed to explain the above results. Grafting of PEGMA on the NCC surface was confirmed using FTIR and ITC experiments. In phase separation experiments NCC-g-PEGMA samples showed greater stability in the presence of TTAB compared to unmodified NCC. By comparing ITC and phase separation results, an optimum grafting ratio (PEGMA : NCC) for steric stabilization was also proposed.
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Novel Cellulose Nanoparticles for Potential Cosmetic and Pharmaceutical ApplicationsDhar, Neha January 2010 (has links)
Cellulose is one of the most abundant biopolymers found in nature. Cellulose based derivatives have a number of advantages including recyclability, reproducibility, biocompatibility, biodegradability, cost effectiveness and availability in a wide variety of forms. Due to the benefits of cellulose based systems, this research study was aimed at developing novel cellulosic nanoparticles with potential pharmaceutical and personal care applications. Two different cellulosic systems were evaluated, each with its own benefits and proposed applications.
The first project involves the synthesis and characterization of polyampholyte nanoparticles composed of chitosan and carboxymethyl cellulose (CMC), a cellulosic ether. EDC carbodiimide chemistry and inverse microemulsion technique was used to produce crosslinked nanoparticles. Chitosan and carboxymethyl cellulose provide amine and carboxylic acid functionality to the nanoparticles thereby making them pH responsive. Chitosan and carboxymethyl cellulose also make the nanoparticles biodegradable and biocompatible, making them suitable candidates for pharmaceutical applications. The synthesis was then extended to chitosan and modified methyl cellulose microgel system. The prime reason for using methyl cellulose was to introduce thermo-responsive characteristics to the microgel system. Methyl cellulose was modified by carboxymethylation to introduce carboxylic acid functionality, and the chitosan-modified methyl cellulose microgel system was found to be pH as well as temperature responsive.
Several techniques were used to characterize the two microgel systems, for e.g. potentiometric and conductometric titrations, dynamic light scattering and zeta potential measurements. FTIR along with potentiometric and conductometric titration was used to confirm the carboxymethylation of methyl cellulose. For both systems, polyampholytic behaviour was observed in a pH range of 4-9. The microgels showed swelling at low and high pH values and deswelling at isoelectric point (IEP). Zeta potential values confirmed the presence of positive charges on the microgel at low pH, negative charges at high pH and neutral charge at the IEP. For chitosan-modified methyl cellulose microgel system, temperature dependent behaviour was observed with dynamic light scattering.
The second research project involved the study of binding interaction between nanocrystalline cellulose (NCC) and an oppositely charged surfactant tetradecyl trimethyl ammonium bromide (TTAB). NCC is a crystalline form of cellulose obtained from natural sources like wood, cotton or animal sources. These rodlike nanocrystals prepared by acid hydrolysis of native cellulose possess negatively charged surface. The interaction between negatively charged NCC and cationic TTAB surfactant was examined and it was observed that in the presence of TTAB, aqueous suspensions of NCC became unstable and phase separated. A study of this kind is imperative since NCC suspensions are proposed to be used in personal care applications (such as shampoos and conditioners) which also consist of surfactant formulations. Therefore, NCC suspensions would not be useful for applications that employ an oppositely charged surfactant. In order to prevent destabilization, poly (ethylene glycol) methacrylate (PEGMA) chains were grafted on the NCC surface to prevent the phase separation in presence of a cationic surfactant. Grafting was carried out using the free radical approach.
The NCC-TTAB polymer surfactant interactions were studied via isothermal titration calorimetry (ITC), surface tensiometry, conductivity measurements, phase separation and zeta potential measurements. The major forces involve in these systems are electrostatic and hydrophobic interactions. ITC and surface tension results confirmed two kinds of interactions: (i) electrostatically driven NCC-TTAB complexes formed in the bulk and at the interface and (ii) hydrophobically driven TTAB micellization on the NCC rods. Conductivity and surface tension results confirmed that the critical micelle concentration of TTAB (CMCTTAB) shifted to higher values in the presence of NCC. Phase separation measurements allowed us to identify the formation of large aggregates or hydrophobic flocs depending on the TTAB concentration. Formation of NCC-TTAB complexes in aqueous solutions was confirmed by a charge reversal from negative to positive charge on the NCC rods. The effect of electrolyte in shielding the negative charges on the NCC was observed from ITC, surface tensiometry and phase separation experiments. Several mechanisms have been proposed to explain the above results. Grafting of PEGMA on the NCC surface was confirmed using FTIR and ITC experiments. In phase separation experiments NCC-g-PEGMA samples showed greater stability in the presence of TTAB compared to unmodified NCC. By comparing ITC and phase separation results, an optimum grafting ratio (PEGMA : NCC) for steric stabilization was also proposed.
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SYNTHESIS AND CHARACTERIZATION OF IONICALLY CROSS-LINKED NETWORKS THROUGH THE USE OF ION-PAIR COMONOMERSDeng, Guodong 01 October 2018 (has links)
No description available.
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Synthesis and Characterization of Highly Functional Substituted Stilbene Copolymers and Semi-crystalline Poly(aryl ether sulfone)sMao, Min 28 September 2007 (has links)
Novel, highly functional rod-like copolymers have been synthesized by alternating copolymerization of N, N, Nâ , Nâ -tetraalkyl-4, 4â -diaminostilbenes (TDAS) with maleic anhydride. Dynamic light scattering, 2H solid state NMR and persistence length measurement reveal high chain rigidity of the polymer backbone. Double quantum heteronuclear local field solid state NMR spectroscopy (2Q-HLF Solid State NMR) has been employed to investigate the chain structure of ¹³C labelled copolymer. The torsional angle of the H-13C-13C-H part of the anhydride ring was zero degrees, indicating an all cis configuration of the H-13C-13C-H moiety of the anhydride ring.
Rod-coil block copolymers containing rigid polyampholyte blocks were designed and synthesized by addition-fragmentation chain transfer (RAFT) copolymerization. The rigid polyampholytes blocks were formed by hydrolysis of alternating copolymers and the flexible coil block consists of poly(oligo(ethylene glycol) methacrylate). The rod-coil block copolymers form polyion complex (PIC) aggregates even when the polyampholyte blocks are charge imbalanced. The aggregates did not dissociate upon the addition of high concentrations of NaCl unlike the dissociation of flexible polyampholytes in NaCl solution. These unique solution properties are induced by 'like-charge attractions' of the rigid polyampholytic alternating copolymer chains.
An example, of what is birefringent to be a novel class of material, has been prepared which enables the control of the birefringence of a polymer film by controlling the rotation of aromatic groups pendant to the polymer backbone.
A linear rigid bisphenol monomer, 4,4′-dihydroxyterphenyl (DHTP), has been incorporated into poly(aryl ether sulfone)s (PAES) in a study to impart crystallization to these amorphous polymers. Three bisphenols, 4, 4′-isopropylidenediphenol, 4, 4′-(hexafluoroisopropylidene)diphenol and 4,4′-dihydroxybiphenyl have been copolymerized with DHTP and dichlorodiphenylsulfone. Only the segmented polysulfone containing 50% BP and 50% DHTP was semi-crystalline. This PAES had a melting temperature (Tm) 320°C in the first heating cycle of a DSC measurement and the presence of crystallites was confirmed by wide angle X-ray diffraction (WAXS). / Ph. D.
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Stimulus-responsive Microgels: Design, Properties and ApplicationsDas, Mallika 31 July 2008 (has links)
Materials science today is a multidisciplinary effort comprising an accelerated convergence of diverse fields spanning the physical, applied, and engineering sciences. This diversity promises to deliver the next generation of advanced functional materials for a wide range of specific applications. In particular, the past decade has seen a growing interest in the development of nanoscale materials for sophisticated technologies. Aqueous colloidal microgels have emerged as a promising class of soft materials for multiple biotechnology applications. The amalgamation of physical, chemical and mechanical properties of microgels with optical properties of nanostructures in hybrid composite particles further enhances the capabilities of these materials. This work covers the general areas of responsive polymer microgels and their composites, and encompasses methods of fabricating microgel-based drug delivery systems for controlled and targeted therapeutic applications.
The first part of this thesis is devoted to acquainting the reader with the fundamental aspects of the synthesis, functionalization and characteristic properties of stimulus-responsive microgels constructed from poly(N-isopropylacrylamide) (poly(NIPAm)) and other functional comonomers. In particular, the role of electrostatics on the swelling-deswelling transitions of polyampholyte microgels upon exposure to a range of environmental stimuli including pH, temperature, and salt concentration are discussed. The templated synthesis of bimetallic gold and silver nanoparticles in zwitterionic microgels is also described.
The latter part of this thesis focuses on the rational development of microgel-based drug delivery systems for controlled and targeted drug release. Specifically, the development of a biofunctionalized, pH-responsive drug delivery system (DDS) is illustrated, and shown to effectively suppress cancer cells when loaded with an anticancer agent. In another chapter, the design of tailored hybrid particles that combine the thermal response of microgels with the light-sensitive properties of gold nanorods to create a DDS for photothermally-induced drug release is discussed. The photothermally-triggered volume transitions of hybrid microgels under physiological conditions are reported, and their suitability for the said application evaluated. In another component of this work, it is explicitly shown that electrostatic interactions were not needed to deposit gold nanorods on poly(NIPAm)-derived particles, thereby eliminating the need for incorporation of charged functional groups in the microgels that are otherwise responsible for large, undesirable shifts and broadening of the phase transition.
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Stimulus-responsive Microgels: Design, Properties and ApplicationsDas, Mallika 31 July 2008 (has links)
Materials science today is a multidisciplinary effort comprising an accelerated convergence of diverse fields spanning the physical, applied, and engineering sciences. This diversity promises to deliver the next generation of advanced functional materials for a wide range of specific applications. In particular, the past decade has seen a growing interest in the development of nanoscale materials for sophisticated technologies. Aqueous colloidal microgels have emerged as a promising class of soft materials for multiple biotechnology applications. The amalgamation of physical, chemical and mechanical properties of microgels with optical properties of nanostructures in hybrid composite particles further enhances the capabilities of these materials. This work covers the general areas of responsive polymer microgels and their composites, and encompasses methods of fabricating microgel-based drug delivery systems for controlled and targeted therapeutic applications.
The first part of this thesis is devoted to acquainting the reader with the fundamental aspects of the synthesis, functionalization and characteristic properties of stimulus-responsive microgels constructed from poly(N-isopropylacrylamide) (poly(NIPAm)) and other functional comonomers. In particular, the role of electrostatics on the swelling-deswelling transitions of polyampholyte microgels upon exposure to a range of environmental stimuli including pH, temperature, and salt concentration are discussed. The templated synthesis of bimetallic gold and silver nanoparticles in zwitterionic microgels is also described.
The latter part of this thesis focuses on the rational development of microgel-based drug delivery systems for controlled and targeted drug release. Specifically, the development of a biofunctionalized, pH-responsive drug delivery system (DDS) is illustrated, and shown to effectively suppress cancer cells when loaded with an anticancer agent. In another chapter, the design of tailored hybrid particles that combine the thermal response of microgels with the light-sensitive properties of gold nanorods to create a DDS for photothermally-induced drug release is discussed. The photothermally-triggered volume transitions of hybrid microgels under physiological conditions are reported, and their suitability for the said application evaluated. In another component of this work, it is explicitly shown that electrostatic interactions were not needed to deposit gold nanorods on poly(NIPAm)-derived particles, thereby eliminating the need for incorporation of charged functional groups in the microgels that are otherwise responsible for large, undesirable shifts and broadening of the phase transition.
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Ανάπτυξη νέων "ευφυών" κατά συστάδες συμπολυμερών τύπου ομοπολυμερές-στατιστικό συμπολυμερέςΓκοτζαμάνης, Γεώργιος 06 November 2007 (has links)
Στην παρούσα Διδακτορική Διατριβή σχεδιάστηκαν και συντέθηκαν με πολυμερισμό μέσω μεταφοράς ομάδας (group transfer polymerization, GTP) τέσσερα νέα πρότυπα “ευφυή” υδατοδιαλυτά συμπολυμερή, τα οποία αυτοοργανώνονται σε υδατικά διαλύματα σε δομές μικκυλίων ή ελαστικού φυσικού δικτύου, αποκρινόμενα άμεσα σε μεταβολές του pH, της θερμοκρασίας και της ιοντικής ισχύος του διαλύματος. Η καινοτομία των πολυμερών που συντέθηκαν οφείλεται στο γεγονός ότι σε ένα συσταδικό συμπολυμερές ενσωματώθηκε μία στατιστική συστάδα, η οποία παρουσιάζει ιδιότητες που είναι συνδυασμός των ιδιοτήτων των μονομερών που την αποτελούν. Ο γενικός τύπος των πολυμερών που μελετήθηκαν είναι A-b-(B-co-C) και A-b-(B-co-C)-b-A. Η συστάδα Α μπορούσε να είναι υδρόφιλη ή υδρόφοβη ενώ η στατιστική συστάδα ήταν είτε ένας πολυαμφολύτης με ρυθμιζόμενο ισοηλεκτρικό σημείο (ΙΗΣ), είτε μια υδρόφιλη συστάδα με ρυθμιζόμενη κατώτερη κρίσιμη θερμοκρασία διάλυσης (LCST). Ο πολυαμφολύτης φορτίζεται θετικά σε όξινα διαλύματα, καθίσταται ουδέτερος στο ισοηλεκτρικό του σημείο και τέλος φορτίζεται αρνητικά σε διαλύματα με υψηλό pH.
Συμπολυμερή του τύπου A-b-(B-co-C)
Συντέθηκαν τρία διαφορετικά συμπολυμερή αυτού του τύπου: Στην πρώτη περίπτωση η συστάδα Α είναι το υδρόφοβο PMMA και η στατιστική συστάδα είναι ο πολυαμφολύτης P(DEA-co-MAA). Το πολυμερές PMMA-b-P(DEA-co-MAA) σχηματίζει μικκύλια σε υδατικά διαλύματα με τη συστάδα PMMA στον πυρήνα και τη στατιστική συστάδα στην κορώνα να είναι είτε θετικά φορτισμένη σε χαμηλό pH είτε αρνητικά φορτισμένη σε υψηλό pH. Στο ΙΗΣ του πολυαμφολύτη το πολυμερές συσσωματώνεται και καθιζάνει. Εμπνεόμενοι από τη δομή των μικκυλιακών συσσωματωμάτων συντέθηκε το επαμφοτερίζον αστεροειδές πολυμερές [PMMA-b-P(DEA-co-MAA)]n, το οποίο δημιουργεί μονομοριακά μικκύλια με πυρήνα PMMA και κορόνα που αλλάζει φορτίο ανάλογα με το pH του διαλύματος.
Στη δεύτερη περίπτωση η στατιστική συστάδα παραμένει o πολυαμφολύτης P(DEA-co-MAA) και η συστάδα Α είναι το υδρόφιλο PEGMA, το οποίο παρουσιάζει LCST και σε υδατικά διαλύματα του πολυμερούς σχηματίζονται τρία είδη μικκυλίων. Στο ΙΗΣ και σε θερμοκρασία δωματίου σχηματίζονται μικκύλια με τη συστάδα P(DEA-co-MAA) στον πυρήνα και την υδρόφιλη συστάδα PEGMA στην κορώνα. Ωστόσο σε θεμρμοκρασία μεγαλύτερη από την LCST και σε pH εκτός της περιοχής του ΙΗΣ του πολυαμφολύτη, η συστάδα PEGMA συρρικνώνεται, οπότε δημιουργούνται μυκκίλια με πυρήνα τη συστάδα PEGMA και κορώνα τη συστάδα P(DEA-co-MAA). Σε χαμηλό pH η κορώνα είναι θετικά φορτισμένη, ενώ σε υψηλό είναι αρνητικά φορτισμένη.
Τέλος στο τρίτο πολυμερές η στατιστική συστάδα αποτελείται από ένα υδρόφιλο και ένα υδρόφοβο μονομερές P(EGMA-co-MMA) και η LCST της συστάδας αυτής μειώνεται με αύξηση του ποσοστού του υδρόφοβου μονομερούς. Ο συνδιασμός μιας τέτοιας συστάδας και μιας συστάδας κατιονικού πολυηλεκτρολύτη (PDEA) σε ένα δισυσταδικό συμπολυμερές οδηγει σε ένα υλικό με πλούσιες ιδιότητες επηρεαζόμενες από τη θερμοκρασία και το pH. Σε χαμηλές θερμοκρασίες και όξινο περιβάλλον είναι μοριακά διαλυτό, αφού και οι δύο συστάδες είναι υδρόφιλες. Με αύξηση του pH ή της θερμοκρασίας συμπολυμερές αυτο-οργανώνεται αυτόματα σε δύο διαφορετικά μικκυλιακά συσσωματώματα με τον πυρήνα και την κορώνα να εναλλάσσονται μεταξύ τους (“σχιζοφρενική” συμπεριφορά). Τέλος με ταυτόχρονη αύξηση του pH και της θερμοκρασίας το συμπολυμερές καταβυθίζεται.
Συμπολυμερή του τύπου A-b-(B-co-C)-b-A
Με βάση το πολυμερές PMMA-b-P(DEA-co-MAA) συντέθηκε ο τηλεχηλικός πολυαμφολύτης PMMA-b-P(DEA-co-MAA)-b-PMMA. Σε διαλύματα του πολυμερούς και σε pΗ έξω από την περιοχή του ΙΗΣ του πολυαμφολύτη, δημιουργούνται συσσωματώματα πεπερασμένου μεγέθους (στην ημιαραιή περιοχή συγκεντρώσεων), ενώ σε πυκνά διαλύματα σχηματίζεται άπειρο φυσικό δίκτυο. Υδατοπηκτώματα του πολυμερούς είναι δυνατό να δημιουργηθούν και από διόγκωση πολυμερικών φιλμ με απορρόφηση ύδατος. Το δίκτυο που σχηματίζεται έχει ελαστική συμπεριφορά τόσο σε χαμηλό όσο και σε υψηλό pH. / In the present thesis four new model and “smart” water-soluble copolymers were designed and synthesized via the group transfer polymerization method. These copolymers self-assemble in aqueous solutions into micelles or elastically physical network (depending on the copolymer architecture), responding readily to changes of the external stimuli such as pH, temperature and ionic strength. The innovation of these polymers is due to the fact that a block copolymer incorporates a statistical block, the physicochemical properties of which, result from combination of the properties of the structural monomers. These copolymers had general type A-b-(B-co-C) or A-b-(B-co-C)-b-A. The homopolymer block A could be either hydrophilic (neutral or cationic) or hydrophobic, while the statistical block (B-co-C) was either a polyampholyte with tunable isoelectric point (IEP), or a hydrophilic block with tunable lower critical solution temperature (LCST). The polyampholyte block could be positively charged in acidic conditions and negatively charged in basic conditions, while at the IEP became neutral.
Copolymers of the type A-b-(B-co-C)
Three different copolymers of the type A-b-(B-co-C) were synthesized. In the first case block A was the hydrophobic PMMA and the statistical block was the polyampholyte P(DEA-co-MAA). When the copolymer PMMA-b-P(DEA-co-MAA) was dissolved in aqueous media, spherical micelles with PMMA core and P(DEA-co-MAA) corona were formed at room temperature and at pH out of the IEP region. At the IEP the copolymer precipitated from the solution due to the neutralization of the statistical polyampholyte block. Inspired by the morphology of the micelles formed by the linear copolymer PMMA-b-P(DEA-co-MAA), the star amphoteric copolymer was synthesized [PMMA-b-P(DEA-co-MAA)]n, which forms unimolecular PMMA-core micelles and corona that changes the charge sign upon changing the solution pH.
In the second case the statistical block was the same as above, while the homopolymer block consisted of the hydrophilic PEGMA, which exhibits LCST and becomes hydrophobic above it. Due to the double sensitivity of this copolymer to pH and temperature, three types of micelles were formed in aqueous solutions. At the IEP and room temperature neutral-corona micelles were formed, at which the core consisted of the statistical P(DEA-co-MAA) block. Multimolecular association took place also at temperatures above LCST of the PEGMA block and at pH below and above the IEP of the polyampholyte Block. In the latter cases PEGMA block formed the core of the micelles.
Finally, in the third copolymer the statistical block P(EGMA-co-MMA) consisted of one hydrophilic and one hydrophobic monomer and its LCST was reduced by increasing the MMA content. The combination of this block with the weak cationic polyelectrolyte PDEA block resulted in a double hydrophilic, double-responsive polymeric system. At ambient temperature and acidic environment the P(EGMA-co-MMA)-b-PDEA copolymer was molecularly dissolved. By increasing either the pH or the temperature of the solution, “schizophrenic” PDEA-core or P(EGMA-co-MMA)-core micelles were formed, respectively. With simultaneous increment oh pH and temperature the copolymer precipitated.
Copolymers of the type A-b-(B-co-C)-b-A
Inspired by the copolymer PMMA-b-P(DEA-co-MAA), the triblock telechelic polyampholyte PMMA-b-P(DEA-co-MAA)-b-A was prepared. Physical networks of this copolymer were formed at pH values out of the isoelectric point (IEP) region of the polyampholyte block. The hydrogel was formed by water absorbion of a dry polymer film and exhibited elastic behavior at acidic as well as at basic conditions. Finally in the semi-dilute regime a large number of polymer chains incorporated to form finite size clusters. These aggregates increased their size by increasing the ionization degree of the polymer chain, as a result of the electrostatic repulsive forces between the charged monomer units.
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Química da parte úmida em processo de fabricação de papel - interações em interfaces sólido-líquido. / Wet end chemistry in papermaking - interactions in solid-liquid interfaces.Silva, Deusanilde de Jesus 02 March 2010 (has links)
Um polieletrólito catiônico (poliamina), com baixo peso molecular e elevada densidade de carga, normalmente aplicado como agente coagulante do lixo aniônico, foi usado para estudos de retenção e drenagem na fabricação de papel. O uso do carboximentil celulose de sódio para simulação do teor de lixo aniônico e seu efeito na retenção de cargas minerais foi uma característica importante para este trabalho. Pode ser observado que o aumento da dosagem do polímero catiônico tanto melhora a retenção de cargas minerais, avaliada pela turbidez do filtrado, quanto melhora a drenagem do sistema, avaliada pela velocidade de escoamento. Entretanto, elevadas dosagens deste polímero comprometeram os resultados destes parâmetros devido à inversão de carga do sistema. Pode também ser confirmado que forças de cisalhamento excessivas prejudicam a retenção de cargas minerais. Ademais, um polianfótero, com peso molecular e densidade de carga elevados, contendo grupos positivo (N-[3-(N,N-dimetilamino)propil]acrilamida), negativo (ácido metileno butanodióico) e nulo (acrilamida) na mesma cadeia, foi testado como agente de resistência a seco do papel. Todos os estudos em nível molecular sobre o comportamento do polianfótero em solução e o seu comportamento de adsorção sobre superfícies modelos carregadas, em diferentes condições de pH e de força iônica, foram importantes para explicar tanto dos fenômenos de adsorção, envolvendo fibras celulósicas e polianfótero, quanto o seu efeito na resistência mecânica do papel. Foi observado que a solubilidade do polímero aumenta à medida que o pH se distancia do seu ponto isoelétrico, pHPIE 7,3, e reduz para valores de pH próximos ao pHPIE. O tamanho das estruturas do polianfótero depende do pH do meio de dispersão. As características de tamanho do polianfótero tanto sob a forma de cadeias individuais ou quanto sob a forma de agregados, foram medidas através da técnica de espalhamento dinâmico de luz. As propriedades viscoelásticas das camadas adsorvidas e a quantidade de polímero adsorvida foram medidas através da técnica da balança microgravimétrica com dissipação de energia. Estas duas determinações, associadas às imagens no microscópio de força atômica, foram importantes para o entendimento dos resultados práticos do uso do polianfótero como agente de resistência a seco do papel. Maiores resultados de resistência do papel, avaliada através da resistência à tração, foram alcançados para valores de pH próximos ao ponto isoelétrico onde foram encontrados o seguinte: (1) maiores tamanhos para as estruturas do polímero em solução, (2) maior quantidade de massa nas camadas adsorvidas e (3) a formação de camadas mais viscoelásticas. O fenômeno de separação de fases, associado à mudança da solubilidade do polímero em solução devido ao balanço dos grupos positivos e negativos ionizados ao longo da faixa de pH estudada, foi considerado o principal aspecto para a variação em tamanho dos agregados. Embora este polímero tenha apresentado comportamento antipolieletrólito devido à expansão da sua cadeia e ao aumento da densidade de carga com o aumento da força iônica, considerando o efeito da força iônica para pH 4,3, o comportamento de adsorção do polianfótero foi avaliado como o comportamento de um polieletrólito monocarregado de alta densidade de carga. Maiores e menores quantidades de massas adsorvidas foram encontradas para valores intermediários e extremos de força iônica, respectivamente. As interações eletrostáticas foram consideradas as principais responsáveis pela adsorção do polímero sobre superfícies carregadas. Entretanto, a blindagem de cargas foi considerada a explicação para os baixos valores de massa adsorvida para valores mais elevados de força iônica. / A cationic polyelectrolyte (polyamine), with low molecular weight and high charge density, usually applied as anionic trash coagulant, was used for the retention and drainage studies in the papermaking. The use of sodium carboxymethyl cellulose to simulate the anionic trash content and its effect on the filler retention was an important feature of the work. It could be noted that the increasing of the cationic polymer dosage improves both the filler retention, evaluated by the turbidity of the filtrate, and the system drainage, evaluated by the flow speed. However, high dosages of this polymer compromised the results of these parameters due to the reversal of the system charge. It can also be confirmed that excessive shear forces affect the filler retention. Furthermore, a polyampholyte, with high molecular weight and charge density, containing positive (N-[3-(N,N- dimethylamino)propyl]acrylamide), negative (methylene butanedioic acid), and neutral (acrylamide) groups in the same chain, was tested as a dry strength agent. All of the studies at molecular level concerning to the polyampholyte behavior in the solution and its adsorption behavior on charged model surfaces at different conditions of pH and ionic strength, were important to explain both the adsorption phenomena, involving cellulosic fibers and polyampholyte, and its impact on the paper strength. It was observed that the polymer solubility increases as the pH moves away from its isoelectric point, pHIEP 7.3, and decreases when the pH approaches close to pHIEP. The sizes of the structures of the polyampholytes depend on the pH of the dispersion medium. Also the size characteristics of polyampholyte, both in individual and aggregated forms, were measured by dynamic light scattering technique. The viscoelastic properties of adsorbed layers, as well as the amount of the adsorbed polymer, were measured by quartz crystal microbalance technique with energy dissipation. These two measurements, associated with the atomic force microscopy images, were important to understand the practical results of polyampholyte usage as a dry strength agent. Best results of paper strength, evaluated by paper strength index, were achieved at pH close to the isoelectric point on which one were found the following features: (1) larger sizes of the polymer structures in solution, (2) higher amount of mass in the adsorbed layers, and (3) the formation of more viscoelastic layers. The phase separation phenomenon, associated with the change in the solubility of the polymer due to the balance of the positive and negative groups throughout the studied pH range, was considered the main aspect for the variation in size of the aggregates. Although this polymer shows antipolyelectrolyte behavior due to the expansion of the its chain and the increasing in charge density with the ionic strength, considering the effect of ionic strength at pH 4.3, the adsorption behavior of polyampholyte was evaluated as a monocharged polyelectrolyte behavior with high charge density. Major and minor amounts of adsorbed masses were found for intermediates and extremes values of ionic strength, respectively. The electrostatic interactions were considered the main cause of the adsorption on charged surfaces. However, the electrostatic screening was considered the explanation for the low values of adsorbed mass at higher values of ionic strength.
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