The
fracturing and friction of coffee beans during grinding generates electricity
that causes coffee particles to clump together and stick to the grinder.
Researchers report Dec. 6 in the journal Matter that
coffee beans with higher internal moisture produce less static electricity,
which means less coffee is wasted and there is less mess to clean up.
This effect can be simulated by adding a
small amount of water to beans immediately before grinding them. The team also
showed that grinding with a splash of water produces more consistent and
intense espresso.
"Moisture, whether it's residual
moisture inside the roasted coffee or external moisture added during grinding,
is what dictates the amount of charge that is formed during grinding,"
says senior author Christopher Hendon, a computational materials chemist at the
University of Oregon.
"Water not only reduces static electricity and therefore reduces mess as you're grinding,
but it can also make a major impact on the intensity of the beverage and,
potentially, the ability to access higher concentrations of favorable
flavors."
These improvements to coffee extraction
could have massive economic implications for the coffee industry, which is
worth $343.2 billion or 1.5% of the US gross domestic product, the researchers say. "Pushing the concentration
up by 10%–15% for the same dry coffee mass has huge implications for saving
money and improving quality," says Hendon.
That coffee grinding produces static
electricity has long been known within the coffee industry, where this
electrification causes clumping and occasional zaps, but little was known about
how different coffee attributes contribute to this phenomenon or how it impacts
brewing. To identify factors associated with static electricity generation
during coffee grinding, Hendon teamed up with volcanologists who study similar
electrification processes during volcanic eruptions.
This video shows how coffee behaves when grinding
with and without a splash of water. Credit: Joshua Mendez Harper.
"During eruption, magma breaks
up into lots of little particles that then come out of the volcano in this big
plume, and during that whole process, those particles are rubbing against each
other and charging up to the point of producing lightning," says first
author and volcanologist Joshua Méndez Harper at Portland State University.
"In a simplistic way, it's similar to grinding coffee, where you're taking
these beans and reducing them to fine powder."
The researchers measured the amount
of static electricity produced when they ground different commercially and
in-house roasted coffee beans that varied by factors including country of
origin, processing method (natural, washed, or decaffeinated), roast color, and
moisture content. They also compared the impact of grinding coarseness on the
amount of electricity produced.
There was no association
between static electricity and the coffee's country of origin or processing
method, but the researchers did find associations between electrification
and water content, roast color, and particle size. Less electricity was
produced when coffee had a higher internal moisture content and when coffee was ground at a coarser setting.
Light roasts produced less charge,
and this charge was more likely to be positive, while darker roasts—which also
tend to be drier—charged negatively and produced more overall charge. The
researchers also showed that dark roast coffees produce much finer particles
than light roasts when ground at the same setting.
Next, the team tested whether
grinding with water changed the way espresso is brewed. When they compared
espresso made with identical coffee beans ground either with or without a splash of water,
they found that grinding with water resulted in a longer extraction time and a
stronger brew. Grinding with water also resulted in espresso shots that were
more similar from shot to shot, overcoming a major hurdle for baristas and
industrial coffee brewers.
Though they only tested espresso,
the researchers say these benefits would apply to many other brewing methods.
"The central material benefit of adding water during grinding is that you
can pack the bed more densely because there's less clumping," says Hendon.
"Espresso is the worst
offender of this, but you would also see the benefit in brew formats where you
pour water over the coffee or in small percolation systems like a stovetop
Bialetti. Where you're not going to see a benefit during brewing is for methods
like the French press, where you submerge the coffee in water."
The researchers plan to follow up
with more investigations into how to prepare the perfect coffee. "Now that
we know what grind settings to use to make reproducible espresso, we can start
to try to understand what factors give rise to sensory differences in coffee
taste," says Hendon.
Their work also has implications
beyond the daily brew, as the electrification of granular materials is an
active area of research in material science, geophysics, and engineering.
"It's sort of like the start of a joke—a volcanologist and a coffee expert walk into a bar and then come out with a paper," says Méndez Harper, "but I think there are a lot more opportunities for this sort of collaboration, and there's a lot more to know about how coffee breaks, how it flows as particles, and how it interacts with water. These investigations may help resolve parallel issues in geophysics—whether it's landslides, volcanic eruptions, or how water percolates through soil."
by Cell Press
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