Hold the Mayonnaise
One promising aspect of US nuclear fusion research may depend on a common kitchen condiment.
To recreate the conditions necessary for fusion reactions, physicists sometimes use something called inertial confinement studies. In this case, that means using gas, frozen inside pea-sized metal pellets, which are placed in a centrifugal chamber and bombarded with high-powered lasers that compress the gas and heat it up to a few million Kelvin.
This all happens in a matter of nanoseconds and, according to Phys.org, tends to have an unwanted side effect — the pellets often explode before reaching fusion conditions. In order to take the concept further, scientists need to better understand the physics at play.
And that’s where mayo comes in.
Arindam Banerjee, an associate professor of mechanical engineering and mechanics at Lehigh University, studies the dynamics of materials in extreme environments. He and his team have built several devices to measure forces in inertial confinement studies.
One subject of their investigations is the phenomenon of instability between materials of two different densities under extreme conditions, like the pellets and gas, known as Rayleigh-Taylor instability. Banerjee likens it to the air inside a balloon.
“As the balloon compresses, the air inside pushes against the material confining it, trying to move out,” Banerjee said in a press release. “At some point, the balloon will burst under pressure. The same thing happens in a fusion capsule. The mixing of the gas and molten metal causes an explosion.”
To understand how molten metal and gasses interact, Banerjee and collaborators looked to mimic the metal. They determined that the material properties and dynamics of the metal at a high temperature are much like those of — drum roll, please — mayonnaise at a low temperature.
In the experiments, the team poured Hellman’s Real Mayonnaise into a Plexiglass container and subjected it to some of the same conditions as the molten metal. Using a high-speed camera and an image processing algorithm, the team computed the parameters associated with the instability.
The results of the study were published today in the journal Physical Review E — a rare example of mayonnaise in scientific literature.
Food for Thought
Understanding the fundamental hydrodynamics and physics of fusion reactions may indeed require out of the box thinking. By applying a creative mindset, and maybe substituting an ingredient or two, physicists can better model the forces at work in various reactions.
Better understanding such forces, according to Banerjee — who’s been experimenting with mayonnaise since at least 2015 — could be of value in helping to solve challenges in geophysics, astrophysics, industrial processes such as explosive welding, and high-energy density physics problems related to inertial confinement fusion.
READ MORE: Behold the mayo: Experiments reveal ‘instability threshold’ of elastic-plastic material [Phys.org]
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