Presented By: Department of Physics
Department Colloquium | Discovery and Design of Emergent Behavior in Soft Materials
Erin Teich (University of Pennsylvania)
Zoom link: https://umich.zoom.us/j/94692610056
Nature organizes itself with often startling complexity at every length scale accessible to human inquiry, resulting in a range of organic and inorganic materials with emergent and varied structural and dynamical properties. An outstanding current goal of materials science is to harness the often subtle self-organization displayed by Nature in order to design materials with tailor-made functionalities in the laboratory. This talk will focus on efforts, in support of that goal, to understand how local structure and local rules give rise to global behavior in soft materials on the nano- and micro-scales. I will first discuss amorphous and jammed colloidal systems, where local structure arises initially due to sample preparation, and subsequently influences rearrangement dynamics and material memory effects under oscillatory shear [1]. I will then discuss systems of colloidal particles with very short-range interactions, where local structure emerges entirely due to entropic considerations. In these systems, local structure can (i) determine whether materials crystallize or fail to do so entirely [2], (ii) tune relaxation behavior in the glass-forming regime [3], and (iii) give rise to crystallization pathways of varying complexity [4,5]. Finally, I will briefly discuss recent work characterizing local microstructure in the biological context of the human brain, and potential applications related to brain development, aging, and neurodegenerative disease [6]. This work collectively demonstrates the enormous impact of simple local rules on complex global behavior in material and biological systems, and points toward exciting future directions related to the design of those behaviors.
[1] E.G. Teich, K.L. Galloway, P.E. Arratia, and D.S. Bassett, Science Advances 7, eabe3392 (2021).
[2] E.G. Teich, G. van Anders, and S.C. Glotzer, Nature Communications 10, 64 (2019).
[3] E.G. Teich, G. van Anders, and S.C. Glotzer, Soft Matter 17, 600 (2021).
[4] E.G. Teich, G. van Anders, D. Klotsa, J. Dshemuchadse, and S.C. Glotzer, Proc. Natl. Acad. Sci. USA 113, E669 (2016).
[5] S. Lee, E.G. Teich, M. Engel, and S.C. Glotzer, Proc. Natl. Acad. Sci. USA 116, 14843 (2019).
[6] E.G. Teich, M. Cieslak, B. Giesbrecht, J.M. Vettel, S.T. Grafton, T.D. Satterthwaite, and D.S. Bassett, New Journal of Physics 23, 073047 (2021).
Nature organizes itself with often startling complexity at every length scale accessible to human inquiry, resulting in a range of organic and inorganic materials with emergent and varied structural and dynamical properties. An outstanding current goal of materials science is to harness the often subtle self-organization displayed by Nature in order to design materials with tailor-made functionalities in the laboratory. This talk will focus on efforts, in support of that goal, to understand how local structure and local rules give rise to global behavior in soft materials on the nano- and micro-scales. I will first discuss amorphous and jammed colloidal systems, where local structure arises initially due to sample preparation, and subsequently influences rearrangement dynamics and material memory effects under oscillatory shear [1]. I will then discuss systems of colloidal particles with very short-range interactions, where local structure emerges entirely due to entropic considerations. In these systems, local structure can (i) determine whether materials crystallize or fail to do so entirely [2], (ii) tune relaxation behavior in the glass-forming regime [3], and (iii) give rise to crystallization pathways of varying complexity [4,5]. Finally, I will briefly discuss recent work characterizing local microstructure in the biological context of the human brain, and potential applications related to brain development, aging, and neurodegenerative disease [6]. This work collectively demonstrates the enormous impact of simple local rules on complex global behavior in material and biological systems, and points toward exciting future directions related to the design of those behaviors.
[1] E.G. Teich, K.L. Galloway, P.E. Arratia, and D.S. Bassett, Science Advances 7, eabe3392 (2021).
[2] E.G. Teich, G. van Anders, and S.C. Glotzer, Nature Communications 10, 64 (2019).
[3] E.G. Teich, G. van Anders, and S.C. Glotzer, Soft Matter 17, 600 (2021).
[4] E.G. Teich, G. van Anders, D. Klotsa, J. Dshemuchadse, and S.C. Glotzer, Proc. Natl. Acad. Sci. USA 113, E669 (2016).
[5] S. Lee, E.G. Teich, M. Engel, and S.C. Glotzer, Proc. Natl. Acad. Sci. USA 116, 14843 (2019).
[6] E.G. Teich, M. Cieslak, B. Giesbrecht, J.M. Vettel, S.T. Grafton, T.D. Satterthwaite, and D.S. Bassett, New Journal of Physics 23, 073047 (2021).
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