Atomically thin mechanosensitive membranes for water treatment
Creating a sense of touch for 2D materials
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Mechanically responsive materials are widely exploited by living organisms in nature to perform various biologically-relevant functions, such as protection against predators, morphing, sensing, and actuation. Functionalities often emerge from mechanically driven biochemical processes that can take place at different length scales within the biological material. The stress-induced conformational changes of cell membrane proteins, the mechanically-driven variation of the ionic permeability of cell organelles, the shear-induced rupture of micro-containers, and the orchestrated action of multiple cells in regenerating tissues are examples of mechanically-driven processes that occur at progressively coarser length scales. Such mechanically-driven phenomena control cell membranes' adhesion and gating properties, enable the release of reactive species into the environment and trigger the complex machinery that allows for self-healing, regeneration, and remodeling of tissues.
Inspired by this rich repertoire of biological materials and building on the Module’s findings in Phases 1 and 2 (2014-2022), Module 1 will continue developing bio-inspired materials that mimic the actuation of live tissues and their response to external actuation. In Phase 3 (2022-2026), the team is interdisciplinary, including former members of Modules 1 and 3 plus a new research group from Empa, and combines expertise in polymer chemistry, biophysics, and computation biology.