Effect of Molecular Architecture of PDMAEMA–POEGMA Random and Block Copolymers on Their Adsorption on Regenerated and Anionic Nanocelluloses and Evidence of Interfacial Water Expulsion

Vuoriluoto, Maija; Orelma, Hannes; Johansson, Leena‐Sisko; Zhu, Bao; Poutanen, Mikko; Walther, Andreas; Laine, Janne; Rojas, Orlando J.

doi:10.1021/acs.jpcb.5b07628

Cited by 32 publications

(49 citation statements)

References 58 publications

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“…Previously in our group, we have shown examples of cellulose modification using PISA-inspired latex systems, comprising a cationic poly(2-dimethyl aminoethyl methacrylate) PDMAEMA-based corona. 21,22 Despite the interesting adsorption properties of PDMAEMA, [46][47][48][49] one of the observed challenges is the hydrolysis of the monomer in aqueous media, even at neutral pH, resulting in methacrylic acid-residues along the polymer backbone. 22 Anionic residues in the backbone give rise to lower cationic charge, thus resulting in lower adsorption to anionic surfaces.…”

Section: Introductionmentioning

confidence: 99%

Tailoring adhesion of anionic surfaces using cationic PISA-latexes – towards tough nanocellulose materials in the wet state

et al. 2019

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Section: Introductionmentioning

confidence: 99%

Tailoring adhesion of anionic surfaces using cationic PISA-latexes – towards tough nanocellulose materials in the wet state

et al. 2019

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“…[17][18][19][20] In such a colloidal preparation route it is important to consider the long-range electrostatic interactions between the (typically negatively) charged CNFs and the polymer of choice during nanocomposite formation. [21][22][23] For instance, strongly interacting polymers that lead to flocculation with CNF will not allow to make ordered, nanostructured composites, and thus, quantitative structure/property relationships based 4 on nano-/mesoscale structures and interactions are overruled by microscale structures (flocculates). 6,9,23 This imposes great constraints on the selection of polymers to derive detailed structure/property relationships in order to progress fundamentally and substantially in the understanding of the behavior of such bioinspired, highly reinforced CNF/polymer nanocomposites.…”

Section: Introductionmentioning

confidence: 99%

Understanding Toughness in Bioinspired Cellulose Nanofibril/Polymer Nanocomposites

et al. 2016

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Cellulose nanofibrils (CNFs) are considered next generation, renewable reinforcements for sustainable, high-performance bioinspired nanocomposites uniting high stiffness, strength and toughness. However, the challenges associated with making well-defined CNF/polymer nanopaper hybrid structures with well-controlled polymer properties have so far hampered to deduce a quantitative picture of the mechanical properties space and deformation mechanisms, and limits the ability to tune and control the mechanical properties by rational design criteria. Here, we discuss detailed insights on how the thermo-mechanical properties of tailor-made copolymers govern the tensile properties in bioinspired CNF/polymer settings, hence at high fractions of reinforcements and under nanoconfinement conditions for the polymers. To this end, we synthesize a series of fully water-soluble and nonionic copolymers, whose glass transition temperatures (Tg) are varied from -60 to 130 °C. We demonstrate that well-defined polymer-coated core/shell nanofibrils form at intermediate stages and that well-defined nanopaper structures with tunable nanostructure arise. The systematic correlation between the thermal transitions in the (co)polymers, as well as its fraction, on the mechanical properties and deformation mechanisms of the nanocomposites is underscored by tensile tests, SEM imaging of fracture surfaces and dynamic mechanical analysis. An optimum toughness is obtained for copolymers with a Tg close to the testing temperature, where the soft phase possesses the best combination of high molecular mobility and cohesive strength. New deformation modes are activated for the toughest compositions. Our study establishes quantitative structure/property relationships in CNF/(co)polymer nanopapers and opens the design space for future, rational molecular engineering using reversible supramolecular bonds or covalent cross-linking.

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“…Similarly, detailed QCM-D analysis can be used to explore the interaction of water with molecules at the test surface, and the influence of molecular architecture upon that interaction, such as in the case of synthetic hydrophilic random and block copolymers on different nanocellulose fibril-coated surfaces, which explored the possibility of water expulsion from the interface as a result of copolymer deposition and the driving forces behind that interaction (in this case, predicted to be of an electrostatic nature) [349]. In some cases this too can be linked to pH responsivity, such as in the case of mycolic acid monolayers [109].…”

Section: Protein Adsorption To Surfacesmentioning

confidence: 99%

Polymers and biopolymers at interfaces

Hall

Geoghegan

2018

Rep. Prog. Phys.

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This review updates recent progress in the understanding of the behaviour of polymers at surfaces and interfaces, highlighting examples in the areas of wetting, dewetting, crystallization, and 'smart' materials. Recent developments in analysis tools have yielded a large increase in the study of biological systems, and some of these will also be discussed, focussing on areas where surfaces are important. These areas include molecular binding events and protein adsorption as well as the mapping of the surfaces of cells. Important techniques commonly used for the analysis of surfaces and interfaces are discussed separately to aid the understanding of their application.

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Effect of Molecular Architecture of PDMAEMA–POEGMA Random and Block Copolymers on Their Adsorption on Regenerated and Anionic Nanocelluloses and Evidence of Interfacial Water Expulsion

Cited by 32 publications

References 58 publications

Tailoring adhesion of anionic surfaces using cationic PISA-latexes – towards tough nanocellulose materials in the wet state

Tailoring adhesion of anionic surfaces using cationic PISA-latexes – towards tough nanocellulose materials in the wet state

Understanding Toughness in Bioinspired Cellulose Nanofibril/Polymer Nanocomposites

Polymers and biopolymers at interfaces

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