This photo shows a small steel sphere sitting on a shear-jammed suspension just as it would on an ordinary solid. Removing the shear switches the suspension back to its liquid-like state, causing the sphere to sink. Photo: University of Southampton.New research has identified how liquid-like materials can change into a solid-like state without the addition of extra particles or changes in volume.
Examples of liquid-like materials containing particles, known as dense suspensions, include molten chocolate and clay deposits at the bottom of oceans or rivers. Understanding the 'jamming transition' – when such a system behaves like a solid (if you want to build something on it) or when it flows (important if you want to process it) – could help in the design of new materials that actively employ this transition from fluid-like to solid-like behavior.
The new study, published in Nature, was led by Ivo Peters, lecturer in the Aerodynamics and Flight Mechanics Research Group at the University of Southampton. Ivo, who conducted the work while working at the University of Chicago, said: "Add more cars to traffic or more particles to a liquid and the result is a sudden transformation in behavior from liquid-like flowing to solid-like jammed. We found a second route to jamming that might appear highly counter-intuitive: solidification without addition of extra particles or changes in volume, but instead triggered by stirring.
"We showed how this solidification occurs via fast-moving shear-jamming fronts, which separate the rigidly jammed state from its sluggishly moving precursor. Our findings provide a new understanding of jamming-related phenomena across a wide range of both microscopic and macroscopic systems."
The concept of ‘jamming by shear’ was introduced to explain how frictional fluid materials transition from a flowing to rigid state. So far, however, experimental evidence has been limited to two-dimensional granular systems and most investigations have been theoretical. This new research presents the first systematic experimental study of shear jamming in fully three-dimensional systems.
The experimental study involved rotating a cylinder that was partially submerged in a fluid mixture containing water, glycerol and corn starch. The solid behavior was demonstrated by dropping small (5 mm) spheres onto the continuously sheared material. As more shear was applied to the solution, the spheres' trajectories changed from slowly sinking (unjammed) to re-bounding and remaining on the surface for as long as the shear-stress was applied (jammed).
"Our findings extend shear jamming beyond dry granular materials and demonstrate its relevance to dense particle suspensions too," explained Ivo. "Both have their own state diagrams, and we have shown in a single experimental system how a state diagram can be constructed that is compatible with experiments and simulations in both fields.
"Besides unifying the fields, shear jamming in dense suspensions has its own unique feature: the formation of fast propagating shear-jamming fronts, a phenomenon that does not exist in dry systems."
This story is adapted from material from the University of Southampton, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.