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Divers collected samples of these colorful microbial mats to
understand their role in oxygenating Earth.

Phil Hartmeyer/NOAA Thunder Bay National Marine Sanctuary

'Totally new' idea suggests longer days on early Earth set stage for
complex life

By Elizabeth PennisiAug. 2, 2021 , 11:00 AM

Today, oxygen fuels much of life on Earth, but it wasn't always that
way. Three billion years ago, this gas was scarce in the atmosphere
and oceans. Knowing why oxygen became plentiful could illuminate the
evolution of our planet's flora and fauna, but scientists have
struggled to find an explanation satisfying to all. Now a research
team has proposed a novel link between how fast our planet spun on
its axis, which defines the length of a day, and the ancient
production of additional oxygen. Their modeling of Earth's early
days, which incorporates evidence from microbial mats coating the
bottom of a shallow, sunlit sinkhole in Lake Huron, produced a
surprising conclusion: as Earth's spin slowed, the resulting longer
days could have triggered more photosynthesis from similar mats,
allowing oxygen to build up in ancient seas and diffuse up into the
atmosphere.

That proposal, described today in Nature Geoscience, has intrigued
some scientists. "The rise of oxygen [on Earth] is easily the most
substantial environmental change in the history of our planet," says
Woodward Fischer, a geobiologist at the California Institute of
Technology who was not involved with the work. This study offers "a
totally new flavor of an idea. It's making a connection that people
haven't made before."

Earth was much different when life first took hold about 4  billion
years  ago, with vast shallow seas whose only living creatures were
one-celled. Many of those early microbes were cyanobacteria, which
can form mats on sediments and rock surfaces and today sometimes
cause algal blooms deadly to fish and other aquatic animals. Microbes
that became cyanobacteria evolved the molecular machinery for
photosynthesis early on, letting them convert carbon dioxide and
water into sugars and oxygen. Researchers have long thought these
microbes provided Earth's initial supply of oxygen, over the eons
creating an environment that favored the evolution of aerobic life in
all its forms. But they always puzzled over why about a billion years
passed between the first photosynthetic microbes, which fossils
indicate arose about 3.5 billion years ago, and the first good
geological evidence for a buildup of oxygen.

Researchers already knew, from modeling the Moon's distance from
Earth and the resulting atmospheric and oceanic tides, that the
infant Earth turned much faster on its axis than it does today. Many
agree that 4.5 billion years ago, a day was only about 6 hours long.
By about 2.4 billion years ago, the models predict, the pull of the
Moon had slowed that spin to about a 21-hour day. Earth's rotational
speed then stayed constant for about a billion years, as its
gravitational pull countered the Moon's drag. Those forces fell out
of balance about 700 million years ago, because the resonance cycle
between Earth and the Moon is not completely stable, and the planet's
spin slowed to its current speed, creating a 24-hour day, according
to the models

In 2016, after a chance suggestion, Judith Klatt, a biogeochemist now
at the Max Planck Institute for Marine Microbiology, realized those
slowdowns in Earth's rate of spin mirrored big leaps in atmospheric
oxygen. For example, oxygen first jumped during what's called the
Great Oxygenation Event, some 2.4 billion years ago, and then again
during the Neoproterozoic era, more than a billion years later.
During the Paleozoic, about 400 million years ago, there was a final
major increase in atmospheric oxygen.  

As a postdoc at the University of Michigan, Ann Arbor, Klatt had
studied microbial mats growing on sediments in the Middle Island
Sinkhole in Lake Huron. There, the water is shallow enough for the
cyanobacteria to get enough sunlight for photosynthesis.
Oxygen-depleted water and sulfur gas bubble up from the lake floor,
creating anoxic conditions that roughly approximate conditions of
early Earth.

Scuba divers collected samples of the microbial mats and in the lab,
Klatt tracked the amount of oxygen they released under various day
lengths simulated with halogen lamps. The longer the exposure to
light, the more of the gas the mats released. 

Excited, Klatt and Arjun Chennu, a modeler from the Leibniz Center
for Tropical Marine Research, set up a numerical model to calculate
how much oxygen ancient cyanobacteria could have produced on a global
scale. When the microbial mat results and other data were plugged
into this computer program, it revealed a key interaction between
light exposure and the microbial mats.

Typically, microbial mats "breathe" in almost as much oxygen at night
as they produce during the day. But as Earth's spin slowed, the
additional continuous hours of daylight allowed the simulated mats to
build up a surplus, releasing oxygen into the water. As a result,
atmospheric oxygen tracked estimated day length over the eons: Both
rose in a stepped fashion with a long plateau.

Did longer days fuel oxygen rise?

Models suggest the amount of oxygen on Earth increased in a stepwise
fashion, starting with the Great Oxygenation Event (GOE) about 2.4
billion years ago, followed by a plateau for a "boring billion"
years. Oxygen rose again in the Neoproterozoic Oxygenation Event
(NOE) and Palaeozoic Oxidation Event (POE). Day length rose in the
same stepped pattern, suggesting that the added light boosted
photosynthetic microbes, fueling increases in oxygen.

0 0.25 0.5 0.75 1 Earth age (millions of years ago) 3500 3000 2500
2000 1500 1000 500 0 Oxygen concentration (pO 2 ) 15 21 12 18 24
Estimated day length (hours) Oxygen concentration Estimated day
length GOE NOE POE The "boring billion" years
K. Franklin/Science

This "elegant" idea helps explain why oxygen didn't build up in the
atmosphere as soon as cyanobacteria appeared on the scene 3.5 billion
years ago, says Timothy Lyons, a biogeochemist at the University of
California, Riverside. Because day length was still so short back
then, oxygen in the mats never had a chance to build up enough to
diffuse out. "Long daytimes simply allow more oxygen to escape to the
overlying waters and eventually the atmosphere," Lyons says.

Still, Lyons and others say, many factors likely contributed to the
rise in oxygen. For example, Fischer suspects free-floating
cyanobacteria, not just those in rock-affixed mats, were big players.
Benjamin Mills, an Earth system modeler at the University of Leeds,
thinks the release of oxygen-binding minerals by ancient volcanoes
likely countered the early buildup of the gas at times and should be
factored into oxygen calculations.

Nonetheless, changing day length "is something that should be
considered in more detail," he says. "I'll try to add it to our Earth
system models."

Posted in:

  * Biology
  * Earth

doi:10.1126/science.abl7415

[Pennisi-Li]

Elizabeth Pennisi

Liz is a senior correspondent covering many aspects of biology for 
Science.

  * Email Elizabeth
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