A team of researchers recently announced that they had engineered a new rubber-like solid substance that has surprising qualities. It can absorb and release very large quantities of energy. And it is programmable. Taken together, this new material holds great promise for a very wide array of applications, from enabling robots to have more power without using additional energy, to new helmets and protective materials that can dissipate energy much more quickly.
Source: University of Massachusetts, Amherst
February 2, 2022 – The material is
programmable. This new material holds
great promise for a very wide array of applications, from enabling robots to
have more power without using additional energy, to new helmets and protective
materials that can disperse energy much more quickly.
"Imagine a rubber band," says
Alfred Crosby, professor of polymer science and engineering at UMass Amherst
and the paper's senior author. "You pull it back, and when you let it go,
it flies across the room. Now imagine a super rubber band. When you stretch it
past a certain point, you activate extra energy stored in the material. When
you let this rubber band go, it flies for a mile."
This hypothetical rubber band is made
out of a new metamaterial -- a substance engineered to have a property not
found in naturally occurring materials -- that combines an elastic, rubber-like
substance with tiny magnets embedded in it. This new
"elasto-magnetic" material takes advantage of a physical property
known as a phase shift to greatly amplify the amount of energy the material can
release or absorb.
A phase shift occurs when a material
moves from one state to another: think of water turning into steam or liquid
concrete hardening into a sidewalk. Whenever a material shifts its phase,
energy is either released or absorbed. And phase shifts aren't just limited to
changes between liquid, solid and gaseous states -- a shift can occur from one
solid phase to another. A phase shift that releases energy can be harnessed as
a power source, but getting enough energy has always been the difficult part.
"To amplify energy release or
absorption, you have to engineer a new structure at the molecular or even
atomic level," says Crosby. However, this is challenging to do and even
more difficult to do in a predictable way. But by using metamaterials, Crosby
says that "we have overcome these challenges, and have not only made new
materials, but also developed the design algorithms that allow these materials
to be programmed with specific responses, making them predictable."
The team has been inspired by some of
the lightning-quick responses seen in nature: the snapping-shut of Venus
flytraps and trap-jaw ants. "We've taken this to the next level,"
says Xudong Liang, the paper's lead author, currently a professor at Harbin
Institute of Technology, Shenzhen (HITSZ) in China who completed this research
while a postdoc at UMass Amherst. "By embedding tiny magnets into the
elastic material, we can control the phase transitions of this metamaterial.
And because the phase shift is predictable and repeatable, we can engineer the
metamaterial to do exactly what we want it to do: either absorbing the energy
from a large impact, or releasing great quantities of energy for explosive
movement."
This research, which was supported by
the U.S. Army Research Laboratory and the U.S. Army Research Office as well as
Harbin Institute of Technology, Shenzhen (HITSZ), has applications in any
scenario where either high-force impacts or lightning-quick responses are
needed.
https://www.sciencedaily.com/releases/2022/02/220202134716.htm
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