Oxygen formation in Earth water

In summary: This paper is about an examination of the biogenicity of stromatolites found in the 3400 Ma Strelley Pool Formation, Western Australia. The results of this study suggest that the stromatolites were probably not produced by cyanobacteria, but by a different type of photoautotrophic prokaryote.http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2977412/thanks broThe role of stromatolites in the oxygenation of Earth is a "yes, but..." story. I have a couple hundred papers that show the complexity of the problem. I was, and am, more concerned with astrobiology
  • #36
Fervent Freyja said:
I do think you are right. It may be more right to say that water was locked into the crust as material accreted and later impacts may have contributed some.

Still, this explanation doesn't satisfy me. Something is off. Looking at all the advancements we have made (look at what we can describe about the universe) and comparing it to how little we can explain about the formation of the early Earth makes me uncomfortable.
I wonder if anyone has considered buoyancy in these models? It seems to me water will tend to rise to the surface because the crust is much denser and will tend to sink in water. I know water fills holes in the crust but how deep down do conditions exist for holes to develop?
 
Earth sciences news on Phys.org
  • #37
jim meyer said:
Well let's not nitpick-I agree photosynthesis has added O2 to the atmosphere. My point is free oxygen has always been in the atmosphere at about 10E18kg or so. The fact that much more CO2 was in the early atmosphere(CO2 now in rocks)and dwarfs the other gases. This is not known and I just want you to do a calculation of how much CO2 rocks like calcite, dolomite and other rocks have absorbed from the early atmosphere. Not rocket science in any way.
Not much to ask I suppose, but some of your views are confusingly expressed, to put it diplomatically. Chemically and biologically speaking for example, CO2 is not regarded as free oxygen, and the point is not purely academic, as you will find out if you try inhaling some. I agree that the early Earth's atmosphere would have contained plenty of CO2 until the rocks cooled down to something like 200C. But that is not free O2, and its difference from free O2 would affect all sorts of things from physical atmospheric characteristics to the precipitation of huge quantities of silica from silicates. Photosynthesis of free O2 in large quantities was one of the great pollution events in the (pre)history of the planets where there had never before been more than traces of anything so violently destructive or toxic before. Not merely whole species, but whole ecological complexes were wiped out within a few million years, and probably repeatedly at that during the transition ages.

If that is nit-picking, make the most of it.

Incidentally, while you are at doing your calculations, you might have some fun calculating how much CO2 is dissolved in the ocean right now, compared to how much we have in our atmosphere, and working out how it got there and how long it has been there, and what is important about it.

The natural world is full of surprises.
 
  • #38
jim meyer said:
I wonder if anyone has considered buoyancy in these models? It seems to me water will tend to rise to the surface because the crust is much denser and will tend to sink in water. I know water fills holes in the crust but how deep down do conditions exist for holes to develop?
As it happens, yes, people do consider buoyancy, but in the early planet temperature was far more important. Such water as wasn't firmly bound tended to gasify dramatically, and even today volcanic clouds contain lots of steam apart from their dust. The first oceans probably rained out of volcanic clouds long before they formed any noticeable puddles.

As for holes in the crust, below the top few km they tend to get squoze shut pretty quickly for the simple reason that most rock is plastic under pressure and at temperatures that superheat steam.

Water is generally a very scarce component of our planet and you will find hardly any even in the deep crust, let alone in the mantle. Actually, I did read somewhere of recent evidence that there might be more water in special regions of the mantle I think it was, than in the current oceans, but that still is small beer (if you will excuse the expression) compared to the overall volume and mass of the mantle and crust. Any volcano tapping such a source however, could do a lot of raining, it seems. :biggrin:
 
  • #39
jim meyer said:
Bacteria is life-one of three kinds of life. This form of life might have done the job-or it might have been done by chemistry not involving life at all. Or maybe a little of both. The point is CO2 locked up in rocks was in the atmosphere early on and there is a lot of CO2 locked up in rocks.

Actually that is by no means the point. How many kinds of life bacteria are, is a matter of definition. A lot of folks like to think of them as two kinds, and some prefer more. To argue one way or another one needs to explain first which purposes your classification serves. None of us has done that just here and now, because it does not address the original question.

But photosynthetic bacteria that process CO2 generally dissolve it from the air or use it dissolved in water. In other words, much as plants do. To extract it from rock is not vanishingly rare, but generally is a specialist adaptation to particular ecologies. A bit of a curiosity if you like.
 
  • Like
Likes Fervent Freyja
  • #40
Jon Richfield said:
Not much to ask I suppose, but some of your views are confusingly expressed, to put it diplomatically. Chemically and biologically speaking for example, CO2 is not regarded as free oxygen, and the point is not purely academic, as you will find out if you try inhaling some. I agree that the early Earth's atmosphere would have contained plenty of CO2 until the rocks cooled down to something like 200C. But that is not free O2, and its difference from free O2 would affect all sorts of things from physical atmospheric characteristics to the precipitation of huge quantities of silica from silicates. Photosynthesis of free O2 in large quantities was one of the great pollution events in the (pre)history of the planets where there had never before been more than traces of anything so violently destructive or toxic before. Not merely whole species, but whole ecological complexes were wiped out within a few million years, and probably repeatedly at that during the transition ages.

If that is nit-picking, make the most of it.

Incidentally, while you are at doing your calculations, you might have some fun calculating how much CO2 is dissolved in the ocean right now, compared to how much we have in our atmosphere, and working out how it got there and how long it has been there, and what is important about it.

The natural world is full of surprises.
Well I didn't mean to say CO2 was free oxygen if that is what you mean. The CO2 molecule is mostly oxygen and photosynthesis or inorganic chemistry can free the oxygen therein. There is a lot more CO2 in the ocean than in the atmosphere. Still more than 90% of all the CO2 on our lovely planet is locked in rocks.
 
  • #42
CapnGranite said:
http://www.astrobio.net/news-exclusive/scientists-detect-evidence-oceans-worth-water-Earth's-mantle/
SCIENTISTS DETECT EVIDENCE OF ‘OCEANS WORTH’ OF WATER IN EARTH’S MANTLE

http://science.sciencemag.org/content/344/6189/1265
This is the original paper, from 2014, but is still locked
Thanks yes, that was the one, though I can't remember whether I read the original or a popular version. But the abstract is adequate for our need here for the moment.
Mind you, it is an observation that opens intriguing lines of speculation. But they are rather academic. I bet that when we get to the technological stage of development that permits us to dig so deep, we'll find that the water is too dilute and too salty to be worth extracting.
But then again, if we could get down there, just extracting the water would be an energetically profitable operation...
Enormously, explosively profitable...
Hmmm...
And think about the mineral impurities -- if we can find water so deep, maybe we could find iridium so shallow... :wideeyed:
$$$$$$$$$$$$$$$$!
:biggrin:
 
  • #43
jim meyer said:
Well I didn't mean to say CO2 was free oxygen if that is what you mean. The CO2 molecule is mostly oxygen and photosynthesis or inorganic chemistry can free the oxygen therein. There is a lot more CO2 in the ocean than in the atmosphere. Still more than 90% of all the CO2 on our lovely planet is locked in rocks.
 
  • #44
Mark Harder said:
No, there are bacteria, called anaerobes, that can live in the absence of O2. In fact, there are anaerobes, called obligate anaerobes, that cannot live in the presence of oxygen, i.e. it's a poison to them.

Oh, but if you remember, oxygen is poisonous to most lifeforms anyway, especially humans... :biggrin:

From what I recall O2 levels in the GI tract range from 2-8% and some obligate anaerobes make it a home!
 
  • Like
Likes Jon Richfield
  • #45
I'm not sure that 90% of CO2 per se is "locked in rocks". Large amounts can be locked up in clathrates, but rocks don't typically lock up CO2. This paper shows the complexity of carbonate species in the Earth system:
http://advances.sciencemag.org/content/2/10/e1601278.full
The fate of carbon dioxide in water-rich fluids under extreme conditions

Another interesting paper is:
http://dge.stanford.edu/SCOPE/SCOPE_16/SCOPE_16_1.5.05_Siegenthaler_249-257.pdf
13C/12C Fractionation during CO2 Transfer from Air to Sea

and another:
http://www.columbia.edu/~vjd1/carbon.htm
Carbonate Rocks

1. Carbon dioxide is removed from the atmosphere by dissolving in water and forming carbonic acid

CO2 + H2O -> H2CO3 (carbonic acid)
2. Carbonic acid is used to weather rocks, yielding bicarbonate ions, other ions, and clays

H2CO3 + H2O + silicate minerals -> HCO3- + cations (Ca++, Fe++, Na+, etc.) + clays
3. Calcium carbonate is precipitated from calcium and bicarbonate ions in seawater by marine organisms like coral

Ca++ + 2HCO3- -> CaCO3 + CO2 + H2O
the carbon is now stored on the seafloor in layers of limestone

 
  • #46
https://deepcarbon.net/feature/study-suggests-earth%E2%80%99s-carbon-originated-planetary-smashup#.WAgu6pMrL-a
The challenge is to explain the origin of the volatile elements like carbon that remain outside the core in the mantle portion of our planet,”

https://deepcarbon.net/content/dco-march-2013-press-release#.WAgvnZMrL-Z
Carbon: Quest Underway to Discover its Quantity, Movements, Origin, and Forms in Deep Earth
A small fraction of Earth's carbon is in its atmosphere, seawater and top crusts. An estimated 90% or more is locked away or in motion deep underground — a hidden dimension of the planet as poorly understood as it is profoundly important to life on the surface.

So, it might be correct to say that 90% of carbon is tied up in various ways in the rocks, but not CO
2
 
  • #47
CapnGranite said:
I'm not sure that 90% of CO2 per se is "locked in rocks". Large amounts can be locked up in clathrates, but rocks don't typically lock up CO2. This paper shows the complexity of carbonate species in the Earth system:
http://advances.sciencemag.org/content/2/10/e1601278.full
The fate of carbon dioxide in water-rich fluids under extreme conditions


Good material and much thanks for the URLs. I still haven't read much of the material because I am playing hookey as things are, but one comparatively small, but actually highly important, reservoir is CO2 insecurely "locked" into solution in the deep sea. It has accumulated in deep layers under pressure, not all of it from the atmosphere. There is more than enough to kill us all if it were suitably released. I draw everyone's attention to the history of lake Nyos (https://en.wikipedia.org/wiki/Lake_Nyos) and leave readers unfamiliar with the history and mechanisms, to wonder why it has not yet happened.

And furthermore, given that its escape is inevitable, work out when it can no longer be averted. :wink:

As for "locking in rocks" in other forms than as carbonates or at an even remoter stretch, as organic compounds or inorganic carbides, I'd be surprised if that were important in any practical way. I cannot think of any sort of rock that can retain molecular CO2 except for bubbles in glassy volcanic rocks or pumice, and that is a pretty insignificant fraction, and one that does not generally escape catastrophically except as volcanic explosions. Lots of fun and amazingly photogenic, but percentage-wise trivial.

Non-gaseous forms of carbon (as opposed to CO2) in the Earth are mostly carbonates and organic compounds in the upper crust, but in the lower crust and mantle, carbides and free carbon would dominate, and though I have no information on them, I would bet a few cases of beer that they dominate the planetary carbon reserves. After all, our surface and shallow supplies are mercifully tiny.
 
<h2>1. How did oxygen form in Earth's water?</h2><p>The oxygen in Earth's water is a byproduct of photosynthesis, which is the process by which plants and other organisms convert sunlight into energy. Early photosynthetic organisms, such as cyanobacteria, began producing oxygen as a waste product approximately 2.5 billion years ago. This oxygen eventually accumulated in Earth's atmosphere and dissolved in water, resulting in the oxygen-rich water we have today.</p><h2>2. Why is oxygen important in Earth's water?</h2><p>Oxygen is essential for life on Earth, both on land and in water. In water, oxygen is necessary for the survival of aquatic organisms, including fish and other marine animals. It also plays a crucial role in the cycling of nutrients and the balance of aquatic ecosystems.</p><h2>3. How does oxygen affect the chemistry of Earth's water?</h2><p>Oxygen has a significant impact on the chemistry of Earth's water. It is highly reactive and can combine with other elements to form compounds, such as rust and water itself. Oxygen also plays a crucial role in the oxidation of minerals and the breakdown of organic matter in water.</p><h2>4. Can oxygen levels in Earth's water change?</h2><p>Yes, oxygen levels in Earth's water can change due to various factors, including changes in atmospheric oxygen levels, temperature, and the presence of organisms that consume or produce oxygen. Human activities, such as pollution and climate change, can also affect oxygen levels in water bodies.</p><h2>5. How is the amount of oxygen in Earth's water measured?</h2><p>The amount of oxygen in Earth's water is measured using various methods, including dissolved oxygen meters, which measure the amount of oxygen dissolved in water, and oxygen sensors, which detect changes in oxygen levels. Scientists also use remote sensing techniques, such as satellite imagery, to monitor and measure oxygen levels in large bodies of water.</p>

1. How did oxygen form in Earth's water?

The oxygen in Earth's water is a byproduct of photosynthesis, which is the process by which plants and other organisms convert sunlight into energy. Early photosynthetic organisms, such as cyanobacteria, began producing oxygen as a waste product approximately 2.5 billion years ago. This oxygen eventually accumulated in Earth's atmosphere and dissolved in water, resulting in the oxygen-rich water we have today.

2. Why is oxygen important in Earth's water?

Oxygen is essential for life on Earth, both on land and in water. In water, oxygen is necessary for the survival of aquatic organisms, including fish and other marine animals. It also plays a crucial role in the cycling of nutrients and the balance of aquatic ecosystems.

3. How does oxygen affect the chemistry of Earth's water?

Oxygen has a significant impact on the chemistry of Earth's water. It is highly reactive and can combine with other elements to form compounds, such as rust and water itself. Oxygen also plays a crucial role in the oxidation of minerals and the breakdown of organic matter in water.

4. Can oxygen levels in Earth's water change?

Yes, oxygen levels in Earth's water can change due to various factors, including changes in atmospheric oxygen levels, temperature, and the presence of organisms that consume or produce oxygen. Human activities, such as pollution and climate change, can also affect oxygen levels in water bodies.

5. How is the amount of oxygen in Earth's water measured?

The amount of oxygen in Earth's water is measured using various methods, including dissolved oxygen meters, which measure the amount of oxygen dissolved in water, and oxygen sensors, which detect changes in oxygen levels. Scientists also use remote sensing techniques, such as satellite imagery, to monitor and measure oxygen levels in large bodies of water.

Similar threads

  • Earth Sciences
2
Replies
52
Views
7K
  • Earth Sciences
Replies
25
Views
5K
  • Sci-Fi Writing and World Building
Replies
5
Views
1K
  • Astronomy and Astrophysics
Replies
30
Views
3K
  • Biology and Medical
Replies
3
Views
2K
Replies
3
Views
3K
Replies
6
Views
6K
  • Sci-Fi Writing and World Building
Replies
21
Views
853
  • Earth Sciences
Replies
10
Views
4K
  • Biology and Medical
Replies
2
Views
2K
Back
Top