Self-folding using capillary forces

Abstract

Self-folding broadly refers to the assembly of 3D structures by bending, curving, and folding without the need for manual or mechanized intervention. Self-folding is scientifically interesting because examples of self-folded structures, from plant leaves to gut villi to cerebral gyri, abound in nature. From an engineering and technological perspective, self-folding of sub-millimeter-sized structures addresses major hurdles in nano- and micromanufacturing. At these size scales, it is prohibitively difficult to assemble 3D structures using conventional probes in a scalable, cost-effective, and mass-producible manner. This review focuses on self-folding using surface tension or capillary forces derived from the minimization of liquid interfacial area. Due to favorable downscaling with length, at small scales capillary forces become extremely large relative to forces that scale with volume, such as gravity or inertia, and to forces that scale with area, such as elasticity. We discuss the major demonstrated classes of capillary force assisted self-folding. These classes include the use of rigid or soft and micro- or nanopatterned precursors that are assembled using a variety of liquids such as water, molten polymers, and liquid metals. We outline the underlying physics and highlight important design considerations that maximize rigidity, strength, and yield of the assembled structures. We also discuss applications of capillary self-folding structures in engineering and medicine. Finally, we conclude by summarizing standing challenges and describing future trends.