Thermoresponsive microgels are soft colloids that find widespread use as model systems for soft matter physics. Their complex internal architecture, made of a disordered and heterogeneous polymer network, has been so far a major challenge for computer simulations. In this work, we put forward a coarse-grained model of microgels whose structural properties are in quantitative agreement with results obtained with small-angle X-ray scattering experiments across a wide range of temperatures, encompassing the volume phase transition. These results bridge the gap between experiments and simulations of individual microgel particles, paving the way to theoretically address open questions about their bulk properties with unprecedented nano- and micr...
An important open problem in materials science is whether a direct connection exists between single-...
Thermoresponsive microgels are one of the most investigated types of soft colloids, thanks to their ...
Karg M, Pich A, Hellweg T, et al. Nanogels and Microgels: From Model Colloids to Applications, Recen...
Thermoresponsive microgels are soft colloids that find widespread use as model systems for soft matt...
Microgels are complex macromolecules. These colloid-sized polymer networks possess internal degrees ...
Due to their controlled size, sensitivity to external stimuli, and ease-of-use, microgel colloids a...
Microgels are polymer-based particles which are able to change size and shape during volume phase tr...
Depending on the volume fraction and interparticle interactions, colloidal suspensions can form diff...
We cross-linked Hydropxypropylcellulose (HPC) polymer chains to produce microgel nanoparticles and s...
Microgels are soft colloids that, by virtue of their polymeric nature, can react to external stimuli...
Thermoresponsive microgels are a popular model system to study phase transitions in soft matter, bec...
In contrast to solid colloidal particles, microgels promptly respond to external stimuli such as th...
Microgels are nanometer-to-micrometer-sized cross-linked polymer networks that swell when dispersed ...
Thermoresponsive microgels find widespread use as colloidal model systems, because their temperature...
Microgels are nanometer-to-micrometer-sized cross-linked polymer networks that swell when dispersed ...
An important open problem in materials science is whether a direct connection exists between single-...
Thermoresponsive microgels are one of the most investigated types of soft colloids, thanks to their ...
Karg M, Pich A, Hellweg T, et al. Nanogels and Microgels: From Model Colloids to Applications, Recen...
Thermoresponsive microgels are soft colloids that find widespread use as model systems for soft matt...
Microgels are complex macromolecules. These colloid-sized polymer networks possess internal degrees ...
Due to their controlled size, sensitivity to external stimuli, and ease-of-use, microgel colloids a...
Microgels are polymer-based particles which are able to change size and shape during volume phase tr...
Depending on the volume fraction and interparticle interactions, colloidal suspensions can form diff...
We cross-linked Hydropxypropylcellulose (HPC) polymer chains to produce microgel nanoparticles and s...
Microgels are soft colloids that, by virtue of their polymeric nature, can react to external stimuli...
Thermoresponsive microgels are a popular model system to study phase transitions in soft matter, bec...
In contrast to solid colloidal particles, microgels promptly respond to external stimuli such as th...
Microgels are nanometer-to-micrometer-sized cross-linked polymer networks that swell when dispersed ...
Thermoresponsive microgels find widespread use as colloidal model systems, because their temperature...
Microgels are nanometer-to-micrometer-sized cross-linked polymer networks that swell when dispersed ...
An important open problem in materials science is whether a direct connection exists between single-...
Thermoresponsive microgels are one of the most investigated types of soft colloids, thanks to their ...
Karg M, Pich A, Hellweg T, et al. Nanogels and Microgels: From Model Colloids to Applications, Recen...