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A novel type of foam can form when blowing or frothing is applied to aqueous particle dispersions in the presence of small amounts of a water-immiscible secondary liquid. If the particles have sufficient wettability for both liquids, the process yields a foam in which coated bubbles are embedded in a tenuous network of particles bridged by the secondary liquid and stabilized by capillary forces. First discovered in 2014, these so-called capillary foams show unusual stability and rheological properties in the liquid state. They also provide new avenues for the production and customization of solid foams. The secondary liquid component can be chosen from wide variety of options, including monomers and prepolymers, polymers solutions, waxes and melts. Along with this choice comes a variety of options to solidify the foam, which includes thermal or UV curing, interfacial polymerization or precipitation, solvent extraction, and cooling; these choices largely determine the foam's mechanical properties. The solid dispersion particles, which can be polymeric or inorganic, can impart additional functionality to the foam, such as magnetic, UV absorbing, heat conducting, or antimicrobial properties, to name just a few. Solid capillary foams can be made using materials commonly found in plastics and technical foams, but they can also be based on biocompatible, biodegradable, or even edible ingredients. In this presentation, I will briefly review the structure and material properties of capillary foams known so far and discuss the broad development opportunities of polymer composite foams for a variety of applications.
Katharina Hornberg was born on 01 July 1994 in Oberhausen, Germany. After graduating from high school in 2013, Ms Hornberg studied mechanical engineering at RWTH Aachen University. In 2014 and 2015, she was a member of the Formula Student Team at RWTH Aachen University, where she gained her first experience of processing plastics. She subsequently decided to specialise in plastics technology in her Bachelor's degree. In 2017, Ms Hornberg completed an internship at the injection molding machine manufacturer Arburg GmbH + Co KG and conducted her first injection molding tests there. Ms Hornberg was enthusiastic about the processing of plastics in injection moulding, so she analysed the geometric and process similarity for transferring machine-learned process knowledge in injection molding in her Bachelor's thesis. From April 2018 to May 2019, Ms Hornberg studied plastics and textile technology in the master's programme with a specialization in plastics technology to expand her expertise in the field of plastics technology and injection molding. In her Master's thesis, Ms Hornberg focused on the development of a process control strategy based on cavity pressure for injection molding. During her Master's studies, Ms Hornberg worked as a student assistant at the Institute of Plastics Processing (IKV) for the entire time. Since June 2019, Ms Hornberg works as a research assistant at the IKV in the injection molding department and is leading the process control working group. Her main area of research involves the development of new process control strategies for the injection moulding process. 1e1e36bf2d