Reshaping sub-millimetre bubbles from spheres to tori

Shape-changing objects are prized for applications ranging from acoustics to robotics. We report sub-millimetre bubbles that reversibly and rapidly change not only their shape but also their topological class, from sphere to torus, when subjected to a simple pressure treatment. Stabilized by a solid...

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Veröffentlicht in:	Soft matter 2022-06, Vol.18 (25), p.466-4666
Hauptverfasser:	Zhang, Xujun, Jacobeen, Shane, Zhang, Qiang, Khau, Brian, Yunker, Peter, Qi, H. Jerry, Bhamla, Saad, Russo, Paul S
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Sprache:	eng
Schlagworte:	Acoustics Automation Bubbles Expulsion Manufacturing engineering Pressure Proteins Robotics Surface Properties Topology Toruses
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container_title	Soft matter
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creator	Zhang, Xujun Jacobeen, Shane Zhang, Qiang Khau, Brian Yunker, Peter Qi, H. Jerry Bhamla, Saad Russo, Paul S
description	Shape-changing objects are prized for applications ranging from acoustics to robotics. We report sub-millimetre bubbles that reversibly and rapidly change not only their shape but also their topological class, from sphere to torus, when subjected to a simple pressure treatment. Stabilized by a solid-like film of nanoscopic protein "particles", the bubbles may persist in toroidal form for several days, most of them with the relative dimensions expected of Clifford tori. The ability to cross topological classes reversibly and quickly is enabled by the expulsion of protein from the strained surfaces in the form of submicron assemblies. Compared to structural modifications of liquid-filled vesicles, for example by slow changes in solution osmolality, the rapid inducement of shape changes in bubbles by application of pressure may hasten experimental investigations of surface mechanics, even as it suggests new routes to lightweight materials with high surface areas. Manipulating air pressure above suspensions of sub-millimetre, protein-coated bubbles converts them from rods to lollipops to smooth spheres to tori. The sphere-to toroid transition can be reversed at least 4 times.
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subjects	Acoustics Automation Bubbles Expulsion Manufacturing engineering Pressure Proteins Robotics Surface Properties Topology Toruses
title	Reshaping sub-millimetre bubbles from spheres to tori
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