Life Outside Our Planet Without Oxygen and Water

In summary, the Boltzmann brain is a quantum fluctuation in the vacuum after a time interval of years. It reminds me of the Stanislaw Lem story about the creature of pure accident, Mymosh the Selfbegotten.
  • #1
Space_Girl
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Hello everyone :)

I have a question.Is it possible for life to exist in other planets without oxygen and water?

I mean just because we need it to survive here on Earth.It doesn’t mean all planets need it to support life as well.
 
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  • #2
Space_Girl said:
Hello everyone :)

I have a question.Is it possible for life to exist in other planets without oxygen and water?

I mean just because we need it to survive here on Earth.It doesn’t mean all planets need it to support life as well.

Do you mean intelligent life or something more simple like bacteria?
 
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  • #3
Yes Intelligent life
 
  • #5
Since we only know of life on Earth (n=1), there is no certain answer.

Not all life on Earth does requires oxygen.
Active life on Earth does require water though.
Dehydrated tardigrades for example are in "suspended animation".

Water is important because much (all?) of the chemistry of underlying life occurs in solution.
This allows molecules to move around and interact more quickly and freely. Guess the same could happen in a gas, but (of course) its never been seen.
 
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  • #6
I wonder if some planets doesn’t need water to support life just because we do here on Earth. Maybe they survive on sources not know to us yet :) just an thought
 
  • #7
Space_Girl said:
Hello everyone :)

I have a question.Is it possible for life to exist in other planets without oxygen and water?

I mean just because we need it to survive here on Earth.It doesn’t mean all planets need it to support life as well.

I’d say yes because life as we know so far is all carbon based from what I know and we all need water. The fact that we don’t know of species that aren’t carbon based or that don’t need water doesn’t mean every other species needs it. It’s not impossible so I reckon it’s possible...
 
  • #8
Vishal Rana said:
I’d say yes because life as we know so far is all carbon based from what I know and we all need water. The fact that we don’t know of species that aren’t carbon based or that don’t need water doesn’t mean every other species needs it. It’s not impossible so I reckon it’s possible...

It might be impossible. Life may only exist under conditions very similar to our own, and may be very recognizable to us. From a chemistry standpoint, carbon appears to be the most viable element that can support life, and it doesn't really have any legitimate competitors.

But since we just don't know, there's always a slim chance it's possible I suppose. But my gut feeling(which is worthless), is that we won't find life elsehwere that isn't carbon based.
 
  • #9
Being carbon-based is not related to breathing oxygen though. Anaerobic bacteria are also carbon-based. The problem is oxygen is good at, well, oxidation. All complex life forms use oxygen, because complex life is power-hungry, just as complex machines. So one needs to find alternative easily available oxidant as a replacement. Not impossible, but oxygen is common and good at what it does, hence more probable. One may argue that free oxygen is not that common, but complex life on Earth didn't evolve until simpler life forms freed some oxygen.

The solvent is another problem. Water also has the advantage of being common molecule in the Universe. It's made of the most abundant element (hydrogen) and end-product of nuclear synthesis in very common stars (oxygen). It is unique among simple molecules in that it could be liquid in fairly large range of conditions (pressure, temperature). There are competitors like methane and ammonia, but they have less favorable thermodynamic properties. Methane is not polar, so it requires completely different biochemistry (possible on cold Titan-like worlds). One can imagine life emerging in a water-ammonia solution, which could be liquid in much lower temperatures than pure water, but if it is so cold, then you probably have a problem with the energy source anyway.
 
  • #10
Space_Girl said:
Yes Intelligent life

Does the Boltzmann brain count?

By one calculation, a Boltzmann brain appears as a quantum fluctuation in the vacuum after a time interval of
86915ec94e1a8bbad54a000d1fc05300cba3122d
years.
 
  • #11
Reminds me of the Stanislaw Lem story

That evening, something emerged at the edge of the dump, not
far from the puddle which had by now dried up, and this something,
a creature of pure accident, was Mymosh the Selfbegotten, who had
neither mother nor father, but was son unto himself, for his
father was Coincidence, and his Mother --Entropy. And Mymosh
rose up from the garbage dump, totally oblivious of the fact that
he had about one chance in a hundred billion jillion raised to
the zillionth power of ever existing, and he took a step, and
walked until he came to the next puddle, which had not as yet
dried up, so that, kneeling over it, he could easily see himself.
And he saw, in the surface of the water, his purely accidental
head, with ears like muffins, the left one crushed and the right
a trifle underdone, and he saw his purely accidental body...

--Truly, I am beautiful, nay, perfect, which clearly implies the
Perfection of All Created Things! Ah, and how good must be the
One Who fashioned me!
http://psychadelicbus.tripod.com/mymosh.txt
 
  • #12
Back to the OP: Have you not seen Cosmos, at least? This is well trodden ground!
 
  • #13
Space_Girl said:
. Maybe they survive on sources not know to us yet :) just an thought
For life of any form to exist, it would have to reproduce and react to its surroundings. Of the elements that are available to any other system of life, there are very few (or none) that have the flexibility of Carbon as a basis. The valency of Carbon allows a massive range of different molecules to be formed. In the popular Science press there are suggestions about Silicon based life but I don't know of any viable suggestions.
There are a number of extremophiles and anaerobic organisms on Earth so why not imagine carbon based life on planets with very different levels of oxygen and water.
 
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  • #14
There has been consideration that there are other temperature ranges, such as on Titan, where the temperature is essentially contolled by the evaporation point of Ethane and Butane at the pressures it is under. There is chemical action there, we know, but water there would be as rock is here, if used it may be the form of Bones or Teeth, perhaps scales etc. Possible carbon life, with a different type of cellular structure, perhaps more crystalline and dependent on microchannels for ethane type blood, and being around us would be like standing right next to pool of lava.

That is the other possibility, creatures living in lava, thinking it fine as any seawater we know. Living on growing crystals, perhaps heated by internal nuclear reaction, as long as one eats the right balance of elements, stays within the right temperature zones, and avoids predation, may well survive to replicate, possibly by fission. We now know water exists down at those depths, and there are plenty of liquids and semiliquids, as well as the metals and perovskites to make it possible. The slow conveyor of subduction zones would provide a nice and varied meal to such critters, and their lives and thus movement would likely be that of tens of thousands of years in scale. Who knows, as several authors have pointed out the Universe is stranger than we Can imagine.

Not that this is highly likely, but it is within the realm of possible until it is completely disproven, and there is a LOT of Universe out there for Nature to try it in.
 
  • #15
sophiecentaur said:
suggestions about Silicon based life
While it's true that Silicon can form complex molecules in a similar way to Carbon, unfortunately most of them are solids which cannot dissolve in water.
Stretching the imagination a bit though, I guess Silicon life is a possibility if it evolves in hot magma instead of water.
 
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  • #16
rootone said:
While it's true that Silicon can form complex molecules in a similar way to Carbon, unfortunately most of them are solids which cannot dissolve in water.
Stretching the imagination a bit though, I guess Silicon life is a possibility if it evolves in hot magma instead of water.

Silane is very much a gas at standard Earth temperatures and pressure. Trisilane boils at 53C and melts and -117C.
Diamond, graphite and fullerrenes are not used in Earth biology equally useless crystaline silicon.

sophiecentaur said:
For life of any form to exist, it would have to reproduce and react to its surroundings. Of the elements that are available to any other system of life, there are very few (or none) that have the flexibility of Carbon as a basis. The valency of Carbon allows a massive range of different molecules to be formed. In the popular

In silicone you have lots of flexibility. Carbon chemistry uses very small building blocks like a sugar ring, amino acid, or lipid chain. Silicone particles can suspend in water The base units can be hundreds or thousands of atoms. Complex process can be executed using arrays of suspended silicone. It can form rings and chain. You can add reactive surfaces to parts.
 
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  • #17
Assuming we are dealing with a chemical basis for life, then there are couple of fundamental limits (absent technological creation of life): (1) Life seems to require complex chemicals, like RNA, in order to reproduce and diversify. That means you can't overheat them: Every bond in your hypothetical complex molecule has to be strong enough to withstand the heat of the environment long enough to reproduce. I suspect you will find that you need many atoms whose bonds are weaker than silicates to build up a sufficiently complex molecule, so you can't take silicates to be representative of high-temperature biochemistry. (This is not my area of expertise, though, so perhaps someone with a high-temp chem background can weight in.)

(2) There has to be enough time to evolve those complex chemicals. Substantial levels of carbon and other non-hydrogen atoms have only existed for a few billion years longer than on Earth. (And the entire universe less than 10 GY longer.) Not a short time, to be sure, but if you wait for (e.g.) ethane-based chemistry on a cold world like Titan, you may have to wait far longer than that to produce complex chemistry, because the reactions slow down so dramatically as the temperature falls.
 
  • #18
JMz said:
Assuming we are dealing with a chemical basis for life, then there are couple of fundamental limits (absent technological creation of life): (1) Life seems to require complex chemicals, like RNA, in order to reproduce and diversify. That means you can't overheat them: Every bond in your hypothetical complex molecule has to be strong enough to withstand the heat of the environment long enough to reproduce. I suspect you will find that you need many atoms whose bonds are weaker than silicates to build up a sufficiently complex molecule, so you can't take silicates to be representative of high-temperature biochemistry. (This is not my area of expertise, though, so perhaps someone with a high-temp chem background can weight in.)

(2) There has to be enough time to evolve those complex chemicals. Substantial levels of carbon and other non-hydrogen atoms have only existed for a few billion years longer than on Earth. (And the entire universe less than 10 GY longer.) Not a short time, to be sure, but if you wait for (e.g.) ethane-based chemistry on a cold world like Titan, you may have to wait far longer than that to produce complex chemistry, because the reactions slow down so dramatically as the temperature falls.

Check colloidal silicates. The SiO2 balls are highly resistant to heat and the bond is too strong. However, the spheres form lots of hydrogen bonds and will react with some chemicals. Silica balls that have strong reactants on the surface are still spheres and they tend to have new properties introduced by the reactant.. A chain of silica balls could, for example, have stretches of hydrophilic spheres and stretches of hydrophobic spheres. That gives the chain the ability to fold up in an organized way where the hydrophilic surfaces face the water. Similar to the organization of protein chains. Also consider amorphous silica alumina. It is used in catalysts. Organic chemistry can take place on and between the particles.
 
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  • #19
stefan r said:
Check colloidal silicates. The SiO2 balls are highly resistant to heat and the bond is too strong. However, the spheres form lots of hydrogen bonds and will react with some chemicals. Silica balls that have strong reactants on the surface are still spheres and they tend to have new properties introduced by the reactant.. A chain of silica balls could, for example, have stretches of hydrophilic spheres and stretches of hydrophobic spheres. That gives the chain the ability to fold up in an organized way where the hydrophilic surfaces face the water. Similar to the organization of protein chains. Also consider amorphous silica alumina. It is used in catalysts. Organic chemistry can take place on and between the particles.
I can believe that there are such compounds, and perhaps they can function in Earth-like environments. My only point about silicates is that, unless every bond in a complex molecule is strong, then the molecule cannot survive high heat, such as lava (as someone suggested) -- even if a silicon "core" could survive it. Hydrogen bonds are particularly weak, in all the examples that I know. (But again, I'm not a chemist.)

Specifically, if liquid water is involved (as the words hydrophobic and hydrophilic indicate), then we are evidently dealing with less extreme temperatures, which might not be too high for such Si-based spheres.
 
  • #20
The time factor is very relevant when discussing possible alternative life chemistries. There are windows in the development of star systems which may allow life forms to start and then to develop before the star ceases to be suitable. Bigger stars than the Sun evolve much quicker and there may not be time before they become hostile. So, before getting too excited about an alternative chemical basis for a life form, that time constraint must be considered. It's all too tempting to be more and more vague about where appropriate conditions could exist and it's easy to stray into the SciFi way of thinking.
Here's another thing to think about. Would we actually recognise the existence of some of those suggested lifeforms? If their timescale were just a bit slower than ours, would we even notice them growing or reacting to an environment that we happen to be sharing? Messages, sent at 0.01 bits per second would probably not be recognised by any of our monitoring systems and it would be the same with bursts of data with THz rates. How wide could we justify a search range to be? It could like Bit Coin Mining; most attempts give a null result.
 
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  • #21
sophiecentaur said:
The time factor... Would we actually recognise the existence of some of those suggested lifeforms?...
We would not recognize anything intelligent on Earth using our current technology. If a transit lines up perfectly you can measure light passing through an atmosphere. Chemistry that is off equilibrium suggests something is happening. Would not guarantee life and certainly would not prove complex life or intelligence. Activities on a planet scale are too dim.

I think 0.01 bits per second would show up as a radio source or any frequency. If something lights up in one(some) image(s) and is gone in another image the change is noteworthy. Przybyllski's star or Alpha Circini have bit rates close to 0.01. Przybyllski oscillates near 12.15 min, 0.0014 cycle per second. The plutonium and lack of iron make Przybyllski stand out too. Not sure which was noticed first.
 
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  • #22
stefan r said:
I think 0.01 bits per second would show up as a radio source or any frequency.
Yes - if you knew where and when to look for it but scanning of a useful band of possible channels of that nature (whether explicitly or with data processing) would 'dilute' the presence of such a signal / information.
 
  • #23
Quite so. It is true that planets near a low-mass star could be warm enough, and they will certainly have time enough, for chemical evolution, even with Earth-like chemistry -- though they would need to find a different energy "harvester" than chlorophyll, because there are too few high-energy photons. (Conversely, hot stars with plenty of those photons might not live long enough.)

I believe we could detect very slow- or fast-moving life as such, not by noticing their motion but by noticing their effect on the environment. For instance, it is easy from space to detect the Earth's oxygen-rich atmosphere, which is out of thermodynamic equilibrium by something like 300 orders of magnitude. Even though you can't see the plants (and they move and grow very slowly by human standards), their effect on the entropy of the atmosphere is so enormous that the mere presence of so much free oxygen is unequivocal evidence of life. Even with different chemistry and much different time scales, we could still detect (widespread) life by its effect on the environment's entropy: Wildly out of equilibrium means life.
 
  • #24
JMz said:
by noticing their effect on the environment.
That's the way to do it. Spot the disused space port or ruined Arecibo style receiving antenna.
 
  • #25
:-) Harder to do than measuring the atmosphere's composition, though.
 
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  • #26
JMz said:
:-) Harder to do than measuring the atmosphere's composition, though.
Except that it could well have changed since the space port was used.
 
  • #27
JMz said:
...
I believe we could detect very slow- or fast-moving life as such, not by noticing their motion but by noticing their effect on the environment. For instance, it is easy from space to detect the Earth's oxygen-rich atmosphere, which is out of thermodynamic equilibrium by something like 300 orders of magnitude...

This atmosphere is 96% oxygen.

I thought it was the 2 ppm methane that makes Earth look lively. Something passed gas. However, I suspect that if JWST measures oxygen and methane around an exoplanet there will be a quick rush to explain how that could occur without living organisms.

sophiecentaur said:
That's the way to do it. Spot the disused space port or ruined Arecibo style receiving antenna.

Our asteroid belt has 25 million objects larger than 100 meters diameter. Over 2 million iron rich asteroids. A dreadnought battleship would look out of place only because of the aspect ratio. After a few impacts and collecting dust for a short time (on astronomical scale) nothing abnormal would be detected from Earth. A free flying Arecibo size receiving antennae would break up quickly. A lot of craters resemble dishes.

Using data existing before 2018 can we prove that 10 Hygiea does not have a replica Arecibo dish?
 
  • #28
stefan r said:
A lot of craters resemble dishes.
I think that was what Arecibo was originally. OK how about the Wall of China? - Or the high traces of radioactivity after a nuclear war?
 
  • #29
stefan r said:
This atmosphere is 96% oxygen.
A delightful item. But of course, it's not out of equilibrium.

I suspect that if JWST measures oxygen and methane around an exoplanet there will be a quick rush to explain how that could occur without living organisms.
Concur, and that effort will be appropriate.
 
  • #30
sophiecentaur said:
I think that was what Arecibo was originally. ..
I looked on wikipedia. Was a sinkhole. :smile:
sophiecentaur said:
...OK how about the Wall of China? ...
NASA
"The only thing you can see from the Moon is a beautiful sphere, mostly white, some blue and patches of yellow, and every once in a while some green vegetation," said Alan Bean, Apollo 12 astronaut. "No man-made object is visible at this scale."

sophiecentaur said:
...Or the high traces of radioactivity after a nuclear war?

There is przybylski's star Would be challenging to get more nuclear than that.

Radioactive isotopes should wash out of an atmosphere fairly quickly (nuclear winter only requires a few loops of Hadley cells, worry about ground water and top soil). Would be a crazy intense war if the atmospheric absorption spectra could show plutonium. I expect the dust kicked up would block the light. The aerosols produced in mushroom clouds have characteristics that are different from volcanic ash. Scattered light would be slightly different. I keep seeing "it is dust" used as evidence that "there is nothing to see here". IMO detailed characterization of dust on exoplanets should be done. Proving that something was a nuclear event can be controversial on Earth .
Gamma ray telescopes
are not very accurate:
The most recent generation of gamma-ray telescopes (2000s) have a resolution of the order of 6 arc minutes in the GeV range (seeing the Crab Nebula as a single "pixel")
Orion or salt water rockets would show up much better than a either surface nuclear war or an epidemic of failed reactors. Supercritical rocket exhaust would be spread out away from the star so most radioactive emissions could get to our detector. Nuclear waste in ground water or sediment would be much harder to detect. A lack of salt water rockets is not evidence that there is no life or that there is no intelligence.
 
  • #31
stefan r said:
There is przybylski's star Would be challenging to get more nuclear than that.
A new one to me.
Sounds like some kind of cosmic rubbish dump.
 
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1. What is the likelihood of life existing outside of Earth without oxygen and water?

The likelihood of life existing without oxygen and water is currently unknown. While it is possible for organisms to survive in extreme environments without these elements, it is not yet known if complex life forms can thrive without them.

2. How do organisms survive without oxygen and water?

Some microorganisms, known as anaerobes, are able to survive without oxygen by using alternative metabolic processes. These organisms may also obtain energy from other sources, such as sulfur or iron compounds. As for water, some organisms have adaptations that allow them to thrive in dry environments, while others may obtain water from their surroundings or produce it through metabolic processes.

3. What types of environments are most likely to support life without oxygen and water?

Life without oxygen and water is most likely to exist in extreme environments, such as deep sea hydrothermal vents, hot springs, or acidic lakes. These environments often have high concentrations of other compounds that can support life, such as methane or sulfur.

4. Could humans survive in a world without oxygen and water?

It is highly unlikely that humans could survive in a world without oxygen and water. Our bodies are adapted to rely on these elements for survival, and without them, our cells would not be able to function properly. However, it is possible that humans could develop technology or genetic modifications to adapt to such environments in the future.

5. How do scientists search for life outside of Earth without oxygen and water?

Scientists use a variety of methods to search for life outside of Earth without oxygen and water. This includes studying extreme environments on Earth to understand the potential for life in similar environments on other planets, analyzing data from space missions to other planets, and developing theoretical models to predict the conditions necessary for life to exist without these elements.

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