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When a traditional robot built from hard plastic or metal suffers damage, it loses functionality, making it unadaptable to a dynamic environment. But a soft, flexible robot offers resiliency in unpredictable situations. Rigid robots continue to be scaled down, but scaling down soft robots in the same way has proved difficult.<\/p>\n
A novel multi-step process has been developed by researchers including Assistant Professor Tommaso Ranzani (ME, MSE) and Assistant Professor Sheila Russo (ME, MSE) to construct microfluidic origami for reconfigurable pneumatic\/hydraulic (MORPH) systems. Their work, initiated when they were postdoctoral fellows at Harvard\u2019s Wyss Institute for Biologically Inspired Engineering and the Harvard John A. Paulson School of Engineering and Applied Sciences and now published in Advanced Materials<\/em><\/a>, details the process and demonstrates its capabilities with the fabrication of a highly complex soft structure.<\/p>\n \u201cIf you have a soft robot you can very easily deal with a highly structured environment and also better deal with the uncertainties of the real world than with traditional, rigid robots,\u201d says Ranzani. \u201cSoft microscale robots for applications like surgery do exist, but they are really simple, just one degree of freedom and they also do not apply that much force to the tissue.\u201d<\/p>\n The MORPH system the researchers built to demonstrate their new process is a 12-layer silicone structure that looks like a peacock spider. The microstructure begins as a 2D object that is then transformed into a 3D structure. The process begins with soft lithography when the 12 separate layers are manufactured, after which laser micromachining precisely cuts the material to form the spider shape before the layers are bonded together.<\/p>\n
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