Abstract
Buckling and wrinkling instabilities are failure modes of elastic sheets that are avoided in the traditional material design. Recently, a new paradigm has appeared where these instabilities are instead being utilized for high-performance applications. Multiple approaches such as heterogeneous gelation, capillary stresses, and confinement have been used to shape thin macroscopic elastic sheets. However, it remains a challenge to shape two-dimensional self-assembled monolayers at colloidal or molecular length scales. Here, we show the existence of a curvature instability that arises during the crystallization of finite-sized monolayer membranes of chiral colloidal rods. While the bulk of the membrane crystallizes, its edge remains fluid like and exhibits chiral ordering. The resulting internal stresses cause the flat membrane to buckle macroscopically and wrinkle locally. Our results demonstrate an alternate pathway based on intrinsic stresses instead of the usual external ones to assemble non-Euclidean sheets at the colloidal length scale.
Highlights
Buckling and wrinkling instabilities are failure modes of elastic sheets that are avoided in the traditional material design
The directional nature of depletion interaction results in all the rods to be aligned along their long axes within the one-rod length thick monolayer membranes (Fig. 1a)
A hitherto unseen curvature instability arises in conjunction with crystallization of colloidal membranes
Summary
Buckling and wrinkling instabilities are failure modes of elastic sheets that are avoided in the traditional material design. A new paradigm has appeared where these instabilities are instead being utilized for high-performance applications Multiple approaches such as heterogeneous gelation, capillary stresses, and confinement have been used to shape thin macroscopic elastic sheets. We show the existence of a curvature instability that arises during the crystallization of finite-sized monolayer membranes of chiral colloidal rods. The resulting internal stresses cause the flat membrane to buckle macroscopically and wrinkle locally. Our results demonstrate an alternate pathway based on intrinsic stresses instead of the usual external ones to assemble non-Euclidean sheets at the colloidal length scale. We show the existence of a unique curvature instability that arises during the crystallization of self-assembled colloidal monolayer membranes composed of aligned chiral colloidal rods[15]. Our work establishes crystallization as a robust method for making colloidal membranes self-shaping materials with tunable surface roughness and curvature
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