Buckling Behaviors at the Interface of Liquid-Solid Systems

Buckling patterns are universal in organs of living organisms. Moreover, the functional realization of these organs is precisely dependent on the deformation of buckling structures, which is also related to the effect of interfacial interaction between liquid and solid surfaces. However, the detection of synergistic reaction between the buckling pattern and the effect of liquid-solid interface is absent. Herein, an experimental simulation of buckling behaviors at the solid-liquid interface, that is, by depositing Au atoms on liquid polydimethylsiloxane (PDMS) is developed. Buckling patterns can be directly created at the interface of Au atoms film and liquid PDMS. Furthermore, it is demonstrated that the orientation of buckling structures can be strictly controlled depending on the frame edges placed on the surface of the liquid PDMS before the deposition. Various ordered buckling patterns, such as parallel wrinkles pattern, magnetic-field-lines-like buckling pattern, and bionic patterns, can be prepared depending on this buckling behavior. The experimental simulation of the buckling behavior at the liquid-solid interface is well promoted, which may be further helpful in understanding the effect of interfacial interaction between liquid and solid surfaces.

Automated summary

Buckling patterns are common in living organisms and play a key role in the functionality of organs, often dependent on the deformation of these buckling structures and the interfacial interaction between liquid and solid surfaces. Experimental simulation of buckling behavior at the liquid-solid interface can result in various ordered buckling patterns, providing insights into the effects of interfacial interaction between liquid and solid surfaces.