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   https://doi.org/10.1021/acsami.0c15056  

   Chester, D.; Theetharappan, P.; Ngobili, T.; Daniele, M.; Brown, A. C. (October 2020, ACS Applied Materials & Interfaces)

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2. Microgel Dynamics Characterization Using SEM

   https://doi.org/10.1063/10.0006350  

   Tietjen, Samantha; Sent, Richard; Fodor, Petru S.; Streletzky, Kiril A. (January 2021, Journal of Undergraduate Reports in Physics)
3. Microgel-Catalyzed Hydrolysis of Nonactivated Disaccharides

   https://doi.org/10.1021/acscatal.0c03401  

   Striegler, Susanne; Sharma, Babloo; Orizu, Ifedi (December 2020, ACS Catalysis)

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4. Behavior and mechanics of dense microgel suspensions

   https://doi.org/10.1073/pnas.2008076117  

   Nikolov, Svetoslav V.; Fernandez-Nieves, Alberto; Alexeev, Alexander (October 2020, Proceedings of the National Academy of Sciences)

   Suspensions of soft and highly deformable microgels can be concentrated far more than suspensions of hard colloids, leading to their unusual mechanical properties. Microgels can accommodate compression in suspensions in a variety of ways such as interpenetration, deformation, and shrinking. Previous experiments have offered insightful, but somewhat conflicting, accounts of the behavior of individual microgels in compressed suspensions. We develop a mesoscale computational model to probe the behavior of compressed suspensions consisting of microgels with different architectures at a variety of packing fractions and solvent conditions. We find that microgels predominantly change shape and mildly shrink above random close packing. Interpenetration is only appreciable above space filling, remaining small relative to the mean distance between cross-links. At even higher packing fractions, microgels solely shrink. Remarkably, irrespective of the single-microgel properties, and whether the suspension concentration is changed via changing the particle number density or the swelling state of the particles, which can even result in colloidal gelation, the mechanics of the suspension can be quantified in terms of the single-microgel bulk modulus, which thus emerges as the correct mechanical measure for these type of soft-colloidal suspensions. Our results rationalize the many and varied experimental results, providing insights into the relative importance of effects defining the mechanics of suspensions comprising soft particles. 

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5. Polyelectrolyte scaling laws for microgel yielding near jamming

   https://doi.org/10.1039/c7sm01518f  

   Bhattacharjee, Tapomoy; Kabb, Christopher P.; O’Bryan, Christopher S.; Urueña, Juan M.; Sumerlin, Brent S.; Sawyer, W. Gregory; Angelini, Thomas E. (January 2018, Soft Matter)

   Micro-scale hydrogel particles, known as microgels, are used in industry to control the rheology of numerous different products, and are also used in experimental research to study the origins of jamming and glassy behavior in soft-sphere model systems. At the macro-scale, the rheological behaviour of densely packed microgels has been thoroughly characterized; at the particle-scale, careful investigations of jamming, yielding, and glassy-dynamics have been performed through experiment, theory, and simulation. However, at low packing fractions near jamming, the connection between microgel yielding phenomena and the physics of their constituent polymer chains has not been made. Here we investigate whether basic polymer physics scaling laws predict macroscopic yielding behaviours in packed microgels. We measure the yield stress and cross-over shear-rate in several different anionic microgel systems prepared at packing fractions just above the jamming transition, and show that our data can be predicted from classic polyelectrolyte physics scaling laws. We find that diffusive relaxations of microgel deformation during particle re-arrangements can predict the shear-rate at which microgels yield, and the elastic stress associated with these particle deformations predict the yield stress. 

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