[♩INTRO]
It seems like every few months, the evolutionary biology community
has something new to get excited about.
Scientists keep finding evidence of incredibly old life.
Like, in March this year, researchers found remnants of ancient thermal vents
buried in rocks in Quebec, with microfossils that clocked in
around 3.7 to 4.28 billion years old.
These would've taken the crown for oldest fossils ever,
but a lot of scientists think that the original estimate was off by a billion years.
So we're still looking for more conclusive evidence of super old life.
And this week, a group from Denmark thinks they have some.
Partially buried under the ice and snow of West Greenland,
there's a belt of rock called the Isua Greenstone Belt.
In the 1970s, geologists dated the belt to be over 3.7 billion years old
some of the oldest rocks on Earth.
And for years, scientists have been probing the belt for evidence of ancient life.
In 2016, researchers found signs of some really old fossils called stromatolites,
which are sediment layers made by bacterial mats.
The wavy shapes and textures of certain layers looked similar
to other stromatolites.
But there wasn't enough proof of organic material,
to suggest they were actually made by microbes.
And now, researchers might have that proof… or at least more clues.
The authors of this new paper published in the journal Nature
used a technique called vibrational spectroscopy
to figure out the composition of tiny pockets in the Greenland rocks.
Specifically, the researchers looked at garnet inclusions,
which are minerals that got trapped inside the rocks
while they were being squished by heat and pressure and forming.
Within the garnet inclusions were small pockets of organic leftovers.
And when scientists bombarded these pockets with infrared light,
all of the molecules and atoms started to vibrate at really specific frequencies.
Using those frequencies, they were able to tell which atoms
were bound to each other and found evidence of
carbon bound to nitrogen, oxygen, and probably phosphorous.
Which points directly towards life.
The more research we can do on these rocks the better,
but these fossils are looking pretty much like
the oldest evidence of life we've ever found… so far.
Now, while a bunch of scientists search for the oldest life on Earth,
others are are focusing on keeping modern-day organisms alive.
Researchers at Caltech have figured out a way to speed up
a chemical process in the ocean that normally takes thousands of years.
And this reaction could help us combat ocean acidification.
The amount of carbon dioxide gas in our atmosphere is steadily climbing,
and it's one of the big players responsible for climate change.
But the biggest concentration of CO2 isn't in the air around us.
It's in the ocean.
CO2 is soluble which means it easily dissolves in water.
And the amount of gas in the air directly impacts how much gets into the water.
Once it's in the ocean, carbon dioxide reacts with water molecules
to form carbonic acid, which breaks up into carbonate ions and hydrogen ions.
And here's where a complex chemical balancing act comes in.
See, carbonate and hydrogen ions can combine to make bicarbonate,
which is much less acidic.
So it can neutralize the dangerous concentration of acid in the water.
But bicarbonate isn't super stable either,
so it'll keep splitting back up into carbonate and hydrogen.
We call this the bicarbonate buffer
something that helps moderate pH levels.
The exact same process is happening in your blood,
and keeps your body working properly.
Now, as the amount of atmospheric CO2 increases,
and more gas dissolves in the ocean,
the bicarbonate buffer starts to wobble.
Which is a huge problem for organisms
that rely on the chemical balance to survive.
But, according to this new research,
there might be a solution scientists have been overlooking.
On the bottom of the ocean floor, there's a graveyard
full of the calcium carbonate skeletons of billions of dead sea creatures,
like corals or plankton.
Over thousands of years, these skeletons dissolve,
releasing their carbonate back into the ocean
and adding to the bicarbonate buffer.
But right now, with so much ocean acidification,
the natural reaction rates are way too slow to help neutralize all this extra acid.
In our bodies, these kinds of reactions can't and don't
take thousands of years to happen, because we have an enzyme
called carbonic anhydrase that catalyzes that reaction.
So the researchers at Caltech thought,
hey, maybe we can use this enzyme to kickstart some chemistry
on the bottom of the ocean floor too.
And after running some experiments in the lab,
they found that it can make the slow part
of the calcium carbonate dissolving reaction around 500 times faster.
So it's not a magic bullet to fix ocean acidification,
but this research could be the first step in making some antacids for the ocean.
By boosting the bicarbonate buffer,
we can combat one of the biggest effects of climate change.
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[♩OUTRO]
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