ScAm - 09.2019

ADVANCES

14 Scientific American, September 2019

CLAUDIA TOTIR

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Riverside and the South Australian Museum
in Adelaide analyzed nearly 1,500 Dickinso-
nia fossils to determine whether the animals
could move on their own. “People have
speculated about [their] being mobile for a
while” because of clues in the fossil record,
Evans says, “but we wanted to examine the
lž†xßx³î…xDîøßxäÿxäxxž³Dickinsonia to
see if we could eliminate all other possible
explanations besides mobility.”
The record includes body fossils as well
as what appear to be “trace fossils”—“foot-
prints” of sorts—that these animals left
behind, hinting they were mobile. Some
scientists suggested, however, that ancient
ocean currents may have picked the crea-
tures up and moved them. Others said the
“footprint” fossils may have actually formed
from specimens that had decayed and then
collapsed when buried in sediment.
But Evans and his team determined that
Dickinsonia indeed seem to have traveled on
their own: possibly tens of meters or more
over their lifetime. The fossil record shows
that these organisms had all moved in dif-
ferent directions; if ocean currents had
shifted them, they would have all been ori-
ented in the same direction, Evans says. The

U ̧lāD³lîßD`x… ̧ä䞧äD§ä ̧ßxþxD§äÇx`ž‰`

pathways left by Dickinsonia. If these were

left by decayed animals, “we would expect

them to be sort of random with respect to

one another,” Evans explains. “And the fact

that we’re seeing trackways [for a single

individual] moving in a preferred direction

suggests an organism moving under its

own power and moving in a direction relat-

ed to its internal biology.”

The evidence indicates Dickinsonia fed in

̧³xäÇ ̧î ̧³îšxäxD‹ ̧ ̧ßÜä ̧ߐD³ž``DßÇxî

and then actively sought a fresh food source,

and they probably did so on relatively short

timescales—over hours or days. Some sci-

entists have hypothesized that these animals

moved by expanding and contracting their

body using muscles, and the new analy sis

supports this idea. Evans notes that al -

though scientists have found evidence for

self-directed animal movement earlier than

Dickinsonia, those animals likely were small-

er and traveled shorter distances. And, he

DlläjÙ5šžäžäîšx‰ßäîxÿxÜßxäxxž³D³

animal move to a new location to feed.”

'îšxßßxäxDß`šxßääDāîšxäx‰³lž³äšx§Ç

to resolve some of the debate over Dickinso-

nia and paint a clearer picture of life’s history

on Earth. “They killed all the other hypothe-

ses” about whether Dickinsonia moved or

not, says Jakob Vinther, a paleobiologist at

the University of Bristol in England, who was

not involved in the study. “This provides us

with more constraints to understand what

[these fossils] tell us about the earliest ani-

mals and animal evolution.” Paleontologist

and mathematician Renee Hoekzema of the

University of Copenhagen agrees. “Against

all odds we are really starting to resolve fun-

damental questions about the nature of the

enigmatic Ediacara biota and thus gaining

insight into the evolution of complex life on

the planet,” explains Hoekzema, who also

was not involved in the study.

Although Dickinsonia did not look like

any known living things today, there are

still some parallels between modern animal

life and archaic creatures such as these.

“We’re seeing very early on the develop-

ment of complex behaviors of mobility and

lž†xßx³î…xxlž³äîā§xäjÚþD³ääDāäÍÙ5šxäx

D³ž­D§` ̧­­ø³žîžxäÿx‰³lxDߧā ̧³ž³

the fossil record are almost as complex as

the ones we have today.” Perhaps life on

ancient Earth was not so alien after all.

— Annie Sneed

PHYSICS

The Perfect

Crepe

Exploring the physics behind

the delicious dessert

With a little help from computer simula-
îž ̧³äD³l‹øžllā³D­žäjx³ž³xxßäšDþx ‰³D§§ā ̧ÇžąxlîšxßD… î ̧…ßxÇx­D¦ž³Í So suggests a new study involving these paper-thin, tricky-to-make pancakes, ÿšžšDßx ̧…îx³‰§§xlÿžîšš ̧ ̧§Dîxj
cheese or jam. By simulating the behavior
of batter poured across a tilting and rotat-
ing hot surface, a pair of engineers—sepa-
rated by half the world but united in their
passion for brunch—mathematically
determined the pan-angle-and-swirl con-
ditions that give rise to ideal crepes.
The investigation was the brainchild of
Mathieu Sellier, an engineer at New Zea-
land’s University of Canterbury, who stud-
žxä‹øžläāäîx­äDîäD§xä…ß ̧­­žß ̧ä̧Ǟ
šD³³x§äî ̧§Džxß‹ ̧ÿäÍxD§ä ̧äxß þxäDä

chief brunch maker in his home and had

often wondered: What’s the best way to

coat the pan thinly and evenly with batter?

In 2016 Sellier mentioned the crepe

conundrum to Edouard Boujo, an engineer

now at École Polytechnique in France,

who studies optimization. They recast the

problem in mathematical terms: How

l ̧xä ̧³x­ž³ž­žąxîšxlž†xßx³`xž³`¦-

ness between a real-world pancake and

D³žlxD§jø³ž… ̧ß­§ā‹Dî ̧³xÕ5šxžßßxäø§îä

appeared in June in Physical Review Fluids.

The optimal technique the duo found—

to pour batter into the hot pan, tilt the pan

to spread it to the edge and swirl to dis-

tribute it evenly—should not come as a

surprise to expert crepe cookers. But its

implications reach beyond the kitchen.

“This is a really good way of simplifying

the problem,” says mathematician Mat-

thew Moore of the University of Oxford,

who was not involved in the study (but

admits to a weakness for savor y crepes). He

says that probing what happens at the tran-

sition between liquid and solid states can

often get complicated. Treating crepe mak-

ing as an optimization problem is a strategy

that could be useful for other tasks.

The crepe-making process is similar

to techniques for adding thin layers to

microchips and evenly applying paint to

a car—applications that the engineers

äDā` ̧ø§lUx³x‰î…ß ̧­îšxžßDÇÇß ̧D`šÍ

“The connection is that you want to

spread your liquid in a thin, uniform lay-

er,” Sellier says. “It’s the same problem in

a lot of cases.” — Stephen Ornes