<i>N</i>‐Isopropylacrylamide/monoalkyl itaconate copolymers and <i>N</i>‐isopropylacrylamide/itaconic acid/dimethyl itaconate terpolymers

Erbi̇l, Candan; Yildiz, Yalçın Şevki; Uyanık, Nurseli

doi:10.1002/pat.1340

Cited by 20 publications

(23 citation statements)

References 30 publications

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“…According to the reported results [16], the shape of the Q v /T curve is changed in accordance with the ionic comonomer content in the copolymers; the equilibrium degree of swelling (Q v ) is higher and the LCST value is shifted to higher temperatures, from 35 to 40°C. Hence, the copolymer hydrogels of NIPAM and ionic comonomer have been studied extensively [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Network structure and temperature dependence swelling behavior of PEG-b-Poly (NIPAM-co-AMPSA) hydrogels in water

Saikia¹,

Mandal

Aggarwal

2012

J Polym Res

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Temperature sensitive hydrogels were prepared by free radical polymerization of N-isopropylacrylamide (NIPAM) and 2-acrylamido-2-methylpropanesulphonic acid (AMPSA) in presence of polyethylene glycol (PEG) as macroinitiator. The aim of the work reported here was to investigate temperature sensitive swelling and deswelling behaviors of the hydrogels in water in order to investigate the effect of various amounts of AMPSA. The result indicated that the incorporation of a hydrophilic ionizable comonomer (AMPSA) affects the temperature sensitivity, swelling/deswelling, morphology and network structure of the hydrogels. The volume fraction in the swollen state (V 2m ), the number average molecular weight between cross-links (M c ), the number of segments between the cross-linked point (N), polymer-solvent interaction parameter (χ), enthalpy (ΔH) and entropy (ΔS) were determined using the Flory-Rehner theory at equilibrium swelling. The negative values of ΔH and ΔS showed that the prepared hydrogels had lower critical solution temperature (LCST). The Flory-Rehner theory of swelling equilibrium was qualitatively satisfied with the experimental data of hydrogels at different temperature.

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Section: Introductionmentioning

confidence: 99%

Network structure and temperature dependence swelling behavior of PEG-b-Poly (NIPAM-co-AMPSA) hydrogels in water

Saikia¹,

Mandal

Aggarwal

2012

J Polym Res

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“…Such spatial inhomogeneities are particularly common in pNIPAAm‐based hydrogels. Their extent is markedly influenced by the experimental conditions during the gelation process: typically, gels made by fast polymerization initiated by large amounts of initiator and/or polymerized at high temperatures are strongly inhomogeneous, whereas those formed by gentle reactions at lower polymerization temperature are more homogeneous 30, 32–34. Despite this knowledge, however, it is unclear to what extent spatial inhomogeneites affect the nature of the volume phase transition of pNIPAAm‐based hydrogels.…”

Section: Introductionmentioning

confidence: 99%

Impact of Polymer Network Inhomogeneities on the Volume Phase Transition of Thermoresponsive Microgels

Seiffert

2012

Macromol. Rapid Commun.

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Thermoresponsive polymer gels exhibit pronounced swelling and deswelling upon changes in temperature, rendering them attractive for various applications. This transition has been studied extensively, but only little is known about how it is affected by nano- and micrometer-scale inhomogeneities in the polymer gel network. In this work, droplet microfluidics is used to fabricate microgel particles of strongly varying inner homogeneity to study their volume phase behavior. These particles exhibit very similar equilibrium swelling and deswelling independent of their inner inhomogeneity, but the kinetics of their volume phase transition is markedly different: while gels with pronounced micrometer-scale inhomogeneity show fast and affine deswelling, homogeneous gels shrink slowly and in multiple steps.

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“…In addition to this macroscopic assessment, several studies have focused on nanometer‐scale concentration fluctuations that occur during gel volume phase transitions, primarily using light and neutron scattering . Again, a particular challenge in this effort is to decouple scattering from the static heterogeneous distribution of the polymer network mesh sizes on length scales of ξ = 1–10 nm, as sketched in Figure C, additional static polymer‐network heterogeneity on length scales of ξ stat = 10–100 nm, as sketched in Figure D, and co‐existing dynamic density fluctuations spanning a scale ξ dyn that covers both the above domains . Several experimentalists have focused on critical concentration fluctuations that arise and diverge at the volume phase transition point of sensitive gels to classify their universality .…”

Section: Microstructural Complexity In Gel Volume Phase Transitionsmentioning

confidence: 99%

“…An additional level of irregularity can be encountered on larger length scales: many polymer networks and gels, both supramolecular and covalent, display spatial inhomogeneities of their crosslinking density on a length scale of several tens of nanometers, as illustrated in Figure D. In covalent polymer networks, such structural complexity is usually a consequence of uncontrolled inhomogeneous chain crosslinking, depending on the experimental conditions during the gel formation, as modeled by replica‐field approaches . In supramolecular polymer networks, similar heterogeneity can arise due to clustering and stacking of the transient crosslinking junctions …”

Section: Introductionmentioning

confidence: 99%

“…The challenge in the attempt to study the effects of nanostructural complexity on the properties of polymer gels is to prepare them such as to exhibit defined degrees of spatial polymer‐network inhomogeneity. This is difficult to achieve, because it must rely on a sound understanding of the impact of the experimental parameters at the moment of the gel formation on the nano‐ and micrometer‐scale structures of the resulting gels . To circumvent this challenge, a simple way to form polymer gels with controlled inhomogeneity is to assemble them from micrometer‐sized particulate gel building blocks, referred to as microgels .…”

Section: Introductionmentioning

confidence: 99%

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Effect and Evolution of Nanostructural Complexity in Sensitive Polymer Gels

Seiffert

2014

Macro Chemistry & Physics

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Sensitive polymer gels consist of swollen networks of crosslinked macromolecules subject to a delicate interplay with their environment, allowing them to be swollen and deswollen or crosslinked and decrosslinked upon external stimulation. Such environmental sensitivity can be realized by the use of covalently crosslinked polymer networks that exhibit critical miscibility with their swelling medium or by the use of transient and reversible, supramolecular chain crosslinking. Both classes of sensitive gels are established and used in a variety of applications. However, to make this truly useful, systematic relations between the structure, dynamics, and properties of these gels must be derived. In addition to the specific trigger of gel responsiveness, a prime factor of influence in this interplay is the nanostructural polymer‐network topology. Whereas a simplistic view of a polymer network is that of an ideal, regular array of monodisperse meshes, real polymer networks often display polydisperse mesh sizes, along with structural imperfections such as loops and dangling chains, and along with further spatial inhomogeneities of their crosslinking density on a length scale of several tens of nanometers. This article summarizes recent effort to consistently probe the impact and temporal evolution of such nanostructural complexity in both gels with critical polymer–solvent miscibility and in gels with transient supramolecular crosslinking. For this purpose, different designed model systems are introduced to control and probe the polymer‐network nanostructural heterogeneity as an experimental variable. This is done using techniques such as rheology, fluorescence recovery after photobleaching, light scattering, and neutron scattering.

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N‐Isopropylacrylamide/monoalkyl itaconate copolymers and N‐isopropylacrylamide/itaconic acid/dimethyl itaconate terpolymers

Cited by 20 publications

References 30 publications

Network structure and temperature dependence swelling behavior of PEG-b-Poly (NIPAM-co-AMPSA) hydrogels in water

Network structure and temperature dependence swelling behavior of PEG-b-Poly (NIPAM-co-AMPSA) hydrogels in water

Impact of Polymer Network Inhomogeneities on the Volume Phase Transition of Thermoresponsive Microgels

Effect and Evolution of Nanostructural Complexity in Sensitive Polymer Gels

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