https://arstechnica.com/science/2023/07/the-namibian-fairy-circle-debate-rages-on-could-it-be-sand-termites-after-all/

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circular reasoning --

Namibian fairy circle debate rages on: Sand termites or Turing
mechanism? [Updated]

Study offers four-point rebuttal to 2022 claim that they're a kind of
eco-Turing pattern.

Jennifer Ouellette - Jul 26, 2023 9:48 pm UTC

Fairy circles in the Namib Desert.
Enlarge / Bare, reddish-hued circular patches in the Namib Desert
known as "fairy circles" are also found in northwestern Australia.
UHH/MIN/Juergens

reader comments

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Himba bushmen in the Namibian grasslands have long passed down
legends about the region's mysterious fairy circles: bare,
reddish-hued circular patches that are also found in northwestern
Australia. In the last 10 years, scientists have heatedly debated
whether these unusual patterns are due to sand termites or to an
ecological version of a self-organizing Turing mechanism. Last year,
a team of scientists made a strong case for what they deemed
definitive evidence of the latter, thus ruling out sand termites, but
was their declaration of victory premature?

A recent paper published in the journal Perspectives in Plant
Ecology, Evolution, and Systematics offers a four-point rebuttal of
those 2022 findings, concluding that sand termites may be to blame
after all. Meanwhile, the authors of that 2022 study have offered a
counter-rebuttal to the rebuttal; there is currently a preprint
undergoing peer review at the same journal.

"The to and fro between opposing camps has often been nothing less
than vitriolic," Michael Cramer, an ecophysiologist at the University
of Cape Town who has studied fairy circles, told The New York Times
last year. That's partly because of how challenging it is to
definitively prove causation for "a long-lived ecological pattern
that cannot be replicated in the lab"--however strenuously one side or
the other may claim to have proven their case.

 

Further Reading

Myth, busted: Formation of Namibia's fairy circles isn't due to
termites

As we've reported previously, the fairy circles can be as large as
several feet in diameter. Dubbed "footprints of the gods," it's often
said they are the work of the Himba deity Mukuru, or an underground
dragon whose poisonous breath kills anything growing inside those
circles. Scientists have their own ideas.

One theory--espoused by study co-author Norbert Jurgens, a biologist
at the University of Hamburg in Germany--attributed the phenomenon to
a particular species of termite (Psammmotermes allocerus), whose
burrowing damages plant roots, resulting in extra rainwater seeping
into the sandy soil before the plants can suck it up--giving the
termites a handy water trap as a resource. As a result, the plants
die back in a circle from the site of an insect nest. The circles
expand in diameter during droughts because the termites must venture
farther out for food.

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The other hypothesis--espoused by Stephan Getzin of the University of
Gottingen--holds that the circles are a kind of self-organized spatial
growth pattern, specifically a Turing pattern, that arise as plants
compete for scarce water and soil nutrients. In his seminal 1952
paper, Alan Turing was attempting to understand how natural,
non-random patterns emerge (like a zebra's stripes), and he focused
on chemicals known as morphogens. He devised a mechanism involving
the interaction between an activator chemical and an inhibitor
chemical that diffuse throughout a system, much like gas atoms will
do in an enclosed box. It's akin to injecting a drop of black ink
into a beaker of water. Normally this would stabilize a system: the
water would gradually turn a uniform gray. But if the inhibitor
diffuses faster than the activator, the process is destabilized. That
mechanism will produce a Turing pattern: spots, stripes, or, when
applied to an ecological system, clusters of ant nests or fairy
circles.

Getzin and colleagues published two papers in 2019 and a third in
2022 about their findings in support of the Turing pattern
hypothesis, with Getzin telling Ars at the time, "We can definitively
dismiss the termite hypothesis" about both Australian and Namibian
fairy circles. He based that statement on the fact that his team
could find no evidence of termite-damaged roots; rather, it was plant
water stress that caused grasses to die inside the bare patch of
fairy circles, based on their topsoil moisture measurements at a
depth of 20 centimeters beneath the fairy circles. The grass plants
self-organize unevenly and hence draw water unevenly to their roots
and through diffusion in the sandy soils. The result is circular
patches of dead grass.

"The support for the hydrodynamic explanation is now very strong, and
the support for the termite cause is very weak," Florida State
University entomologist Walter Tschinkel, told The New York Times
last year. (He was not involved in the 2022 study, but based on his
own research, he supports the water-stress hypothesis.)

Page: 1 2 Next -

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Jennifer Ouellette Jennifer is a senior reporter at Ars Technica with
a particular focus on where science meets culture, covering
everything from physics and related interdisciplinary topics to her
favorite films and TV series. Jennifer lives in Baltimore with her
spouse, physicist Sean M. Carroll, and their two cats, Ariel and
Caliban.
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