Eckert, KathrinKathrinEckertBonsen, Christin JelisaChristin JelisaBonsenHajnal, AnjaAnjaHajnalGmeiner, JohannesJohannesGmeinerHasse, JonahJonahHasseAdrian, MuhammadMuhammadAdrianKarsten, JulianJulianKarstenKißling, PatrickPatrickKißlingPenn, AlexanderAlexanderPennFiedler, BodoBodoFiedlerLuinstra, Gerrit A.Gerrit A.LuinstraSmirnova, IrinaIrinaSmirnova2025-05-142025-05-142025-10-01Fluid Phase Equilibria 597: 114462 (2025)https://hdl.handle.net/11420/55591Stimuli-responsive lyogels are known for their ability to undergo significant macroscopic changes when exposed to external stimuli. While thermo-responsive gels, such as poly-N-isopropylacrylamide (pNIPAM), have been extensively studied across various applications, solvent-induced swelling has predominantly been investigated in aqueous solutions. This study explores the tailoring of lyogel formulations for future applications by controlling their solvent-induced swelling behavior, comparing both homopolymeric and semi-interpenetrating polymer networks (semi-IPNs). It is structured in two parts: the first focuses on characterization techniques, including NMR relaxometry, swelling degree measurements, mechanical testing, and SEM analysis, while the second part delves into swelling kinetic analysis, applying solvent exchange as a stimulus for varying gel formulations and solvents. In contrast to most previous studies, the impact of chemical and physical crosslinking, as well as copolymer inclusion, on the swelling behavior and mechanical properties of lyogels in organic solvents is examined and compared with solvent-induced swelling kinetics measurements. The results demonstrate that increasing chemically crosslinking in homopolymers and physically crosslinking in semi-IPNs enhances mechanical stability, while improving mass transport properties and solvent exchange kinetics. However, increases degree of crosslinking results in a prolonged response time to the solvent exchange stimulus and a reduction in the overall swelling capacity of the lyogels. Furthermore, variations in solvent properties, including molecular size and diffusion rates, significantly influence the swelling kinetics, whereas smaller, faster-diffusing solvents leading to more pronounced solvent spillage effects. Our findings highlight the complex interplay between gel formulation, network structure, and solvent nature in determining the solvent-induced swelling kinetics of lyogels, providing insights into how these materials can be tailored for specific applications especially those requiring short response times and optimized mechanical properties.en0378-38122025Elsevierhttps://creativecommons.org/licenses/by/4.0/Polymer | Semi-IPN | Smart reactors | Solvent-induced | Stimuli-responsive gels | Swelling kineticsNatural Sciences and Mathematics::541: Physical; TheoreticalTechnology::620: Engineering::620.1: Engineering Mechanics and Materials ScienceTechnology::660: Chemistry; Chemical EngineeringJournal Articlehttps://doi.org/10.15480/882.1516810.1016/j.fluid.2025.11446210.15480/882.1516810.15480/882.15062Journal Article