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Biomaterials display microstructures that are geometrically irregular and functionally efficient. Understanding
the role of irregularity in determining material properties offers a new path to engineer materials with superior
functionalities, such as imperfection insensitivity, enhanced impact absorption, and stress redirection. We
uncover fundamental, probabilistic structure–property relationships using a growth-inspired program that
evokes the formation of stochastic architectures in natural systems. This virtual growth program imposes a set
of local rules on a limited number of basic elements. It generates materials that exhibit a large variation in
functional properties starting from very limited initial resources, which echoes the diversity of biological
systems. We identify basic rules to control mechanical properties by independently varying the
microstructure’s topology and geometry in a general, graph-based representation of irregular materials.
The work was published in
Science on 26 August , 2022.
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