UEA Research Shows Oceans Vital For Possibility of Alien Life 97
An anonymous reader writes New research at the University of East Anglia finds that oceans are vital in the search for alien life. So far, computer simulations of habitable climates on other planets have focused on their atmospheres. But oceans play an equally vital role in moderating climates on planets and bringing stability to the climate, according to the study. From the press release: "The research team from UEA's schools of Mathematics and Environmental Sciences created a computer simulated pattern of ocean circulation on a hypothetical ocean-covered Earth-like planet. They looked at how different planetary rotation rates would impact heat transport with the presence of oceans taken into account. Prof David Stevens from UEA's school of Mathematics said: 'The number of planets being discovered outside our solar system is rapidly increasing. This research will help answer whether or not these planets could sustain alien life. We know that many planets are completely uninhabitable because they are either too close or too far from their sun. A planet's habitable zone is based on its distance from the sun and temperatures at which it is possible for the planet to have liquid water. But until now, most habitability models have neglected the impact of oceans on climate.'"
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And how do you know it is bullshit? Do you have better evidence, or are you making it up? Pulling it out of your bottom? Making up "bullshit", as it were?
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Correction (Score:5, Informative)
"Vital For Possibility of Earth-like Alien Life"
A lot of assumptions there.
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the way we know that life adapts is gradual. and energy, while necessary can also be pretty damn detrimental to stability.
while it's possible to say that life can develop in vastly different environments than what we experience here on earth, we don't have infinite resources to use in "exploring" these. We know life has developed on an earthlike planet. :) cutting down the number of planets to only "earth like" ones... still leaves us with too many to ever hope of getting to.
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>still leaves us with too many to ever hope of getting to
Pessimist. If we develop interstellar travel, even at small fractions of light speed, remain expansionistic, and avoid completely eradicating ourselves or transcending as a species we could colonize the whole friggin galaxy in only a few billion years.
Or maybe you meant "we" in a personal sense in which case yeah, barring the surprise development of feasible near-instantaneous (in ship-time of course) travel, we have absolutely no hope of visiting
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:) any fraction of lightspeed would be a monumental achievement. And, as a pessimist i imagine that the time it takes to wipe ourselves off the face of the earth is shorter than the time it takes to get all interstellar with ourselves.
as we get closer to wiping ourselves out, the time it takes to getting interstellar with ourselves increases :)
though, we could do a generational colony ship dealio, but one way trip and eminently hazardous...
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Hmm, now you've got me curious just what it would take. Let's see... human energy consumption in 2008 ~=144,000 TWh = 5*10^20 Joules
E = 1/2mv^2 (for negligibly relativistic speeds), therefore
m = 2E/v^2. And if we're looking to get to 0.1c that gives us...
m = 2*5e20/(0.1c)^2 = 1,112,650 kg
So given an acceleration system that requires minimal reaction mass, with the amount of energy we consumed in 2008 we could get a 1000 metric ton craft up to around 1/10 lightspeed. Eminently doable if we had the politic
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speeding up and slowing down. i seem to remember reading somewhere that slowing down from fractions of light speed are pretty hazardous to the target.
energy consumption on global scales isn't terribly viable... in general.
fusion reactors aren't even a glimmer yet. think they're trying to go for controlled fusion reaction still, and that's getting stonewalled by congressional funding.
i'll change my mind somewhat when we get a little further along to "limitless energy" :)
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> i seem to remember reading somewhere that slowing down from fractions of light speed are pretty hazardous to the target.
Hmm, well I suppose if you were under hard acceleration it probably wouldn't be healthy for anything caught in the exhaust at close range, and depending on just how fast your were going and how hard you were accelerating the deceleration would be worse as the exhaust density builds up in front of you. Still, it's a problem easily mitigated simply by keeping your thrusters pointed wel
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In some SF universes that is codified as a "law" of warfare. e.g. "The Kzinti Lesson : a reaction drive is a weapon in proportion to it's efficiency as a drive."
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Or maybe you meant "we" in a personal sense in which case yeah
You need quite a wide reaching definition of "we" if you want to include many different colonists, spread out over radically different planets, evolving over billions of years. Only a few dozen million years ago "we" were small furry rodents.
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Only a few dozen million years ago "we" were small furry rodents.
Now I have to nitpick. According to Wikipedia, last common ancestor of Rodentia and "us" lived about 90 million years ago, and wasn't a rodent. So, strictly speaking, "we" have never been rodents (furry or not), and 6-7 (dozen million years) is more than "a few" even if you take the last common ancestor.
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Now that could be a challenge - you would need a minimum of 100,000 years just to cross it, probably closer to a million if traveling at only a fraction of light speed and not following a straight path through the intensely radioactive galactic core. But yeah, I suppose if you had a fleet of rogue planets looping through the galaxy at a substantial fraction of light speed with people breeding as fast as possible and getting off at every star they passed near, you could at least get a decent start.
If on the
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Pessimist. If we develop interstellar travel, even at small fractions of light speed, remain expansionistic, and avoid completely eradicating ourselves or transcending as a species we could colonize the whole friggin galaxy in only a few billion years.
Or maybe you meant "we" in a personal sense in which case yeah, barring the surprise development of feasible near-instantaneous (in ship-time of course) travel, we have absolutely no hope of visiting more than the planets in our own system and maybe those of one other star.
Pessimist. I plan to live forever as a brain in a small vat of artificial cerebrospinal fluid connected by electrodes to the controls of a tiny interstellar space ship.
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Well, at least you didn't say as an uploaded mind, so it will still be at least partially you (how much of "you" is a product of biofeedback, hormonal, the extended brain (aka spinal cord), and secondary brain in your intestines? Kinda hard to tell until somebody makes the leap)
Achieving even single-organ immortality will still be a challenge though - are you sure you wouldn't rather survive as a liver in a jar? At least then you'd have impressive natural regeneration abilities to work with...
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Billion? A few tens of million years.
The galaxy is about 100,000 LY across. If we can get to 1% of c, then moving out to cover the galaxy would take (order of) 10 million years transit time. Since you're using generation ships, then while you're in flight you can be preparing a colonisation ship in the c
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I'll admit I was assuming colonizing the whole galaxy wasn't a specific goal but just a side effect of us doing what we've always done. In which case it might take many thousands of years for a small colony of misfits who've integrated generations of interstellar near-zero population growth into their culture to grow to fill a star system to the point that their own misfits start to feel the need to spend generations in interstellar space to get away. After all without FTL there's not many other reasons t
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I'd say that's a racing certainty. It's not a trope I've seen exercised much in SF (a notable exception being "Building Harlequin's Moon [wikipedia.org]" by Larry Niven and Brenda Cooper. The necessity for a mutli-generational approach would tend to cramp things like character development (BHM spans a period IIRC of some 60,000 years, as the colony ship has to lay over to carry out repairs, and in the proc
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I would think you don't worry about motivating the 79th generation, any more than you do on Earth - unless you've got an automated system installing neural clamps at birth you'll have absolutely, positively lost virtually all influence on the culture long before. What you do is put them on a ship big enough that they don't go insane and point it at a distant star around which you've confirmed there's a hospitable panet (gravitational lens telescopes are your friend). Then, assuming nothing unexpected happ
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Like I said, put them into a ship with big enough storage to drop off a colony-forming ship every 10 generations - let them do the deceleration, mine your consumables, and re-supply the mothership. If that's happening every 10-20 generations, then you've got a release valve for your society (something that we don't have at the moment, but designing a society with release valves is one of the influences you can have across the millennia). And i
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Actually such a telescope is relatively easy to build, just a little difficult to get in to position and slow to retarget. But a planetary mass isn't nearly sufficient to examine planetary surfaces over interstellar distances, you need a stellar mass to really see the effect shine. Put the Hubble out at 600+AU and look back at our sun (hidden behind an occluding disc of course) and you've got your gravitational lens. For a world ship, which I'm assuming spends most of it's time coasting, you could easil
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Should have added - that carpenter gets special moral authority from his claimed relation to God, and there's only a handful of individuals in history who've been credited with such significance. You - you're just the dreamer that decided to launch a ship to a distant star. Or are you hoping to grow in legend until your distant descendents come to worship you as well?
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ha, ha, but serious. There's a sea of ideas out there for SF authors to mine, but they don't seem terribly inclined to dip into that particular pond. targeted anthologies ("Dangerous Visions", the Berserker universe) have a decent track record for getting people to play with an idea.
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There's no shortage of people claiming such a relationship with the FSM. On my friend's locked hospital ward the last time he had one of his episodes, there were 4 claimants.
The number who have actually had such a relationship remains the same as the number of gods - zero.
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I reserve my opinion on the number of gods until I see evidence for or against their existence. Certainly many have possessed metaphorical existence, with their priests wielding massive sociological powers in their name, and I have seen enough first-hand evidence of intentional phenomena that stretch the limits of plausibility that I'm willing to entertain the possibility that it might be possible that at least some manner of beings capable of discretely playing the part exist. (Ever read American Gods by
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When we have rovers that can drill into the icy moons, we will be able to test that idea right in our own solar system.
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Not only shouldn't we, we simply can't, because we have no way of knowing.
There is no scientifically valid way to rule out life forms which are unlike our own, because we don't know what they would require or thrive on.
The same as when people say "but why aren't we searching for life which is unlike us", the answer becomes "because we don't know how". There's no basis on which to conclude anything other than "well, we couldn't live there".
At best, we can say a planet is uninhabitable by us, but we really cannot say it is uninhabitable by life we can't even imagine and which is significantly different from what we know.
Anybody who tries to tell you there is no chance of life as we don't know it existing someplace is saying much more than they actually know.
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There is no scientifically valid way to rule out life forms which are unlike our own
I'm pretty sure there are ways to constrain the range of possibilities. One obvious thing is that no life forms will most likely be based on xenon or gold because these elements don't really form the same kind of a wide range of interesting compounds that carbon does. The laws of physics (and chemistry) are the same pretty much everywhere, and just because our brains (and computers) are incapable of reaching more significant conclusions on this issue at this very moment doesn't mean that it's going to stay
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I always viewed it this way: IF there is a significant number of intelligent life forms out there, then more likely than not we are "common", i.e. likely to be "in the middle of the distribution". Therefore I am a [skeptical] carbon jingoist. Also, it seems that intelligence requires certain level of complexity of the physical carrier and not many chemical elements can give rise to vast numbers of complex compounds - the mighty carbon beats them all. Due to historical reasons in my language we call the carb
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Where, precisely, do we know that the laws of physics are different from those we see here? "pretty much everywhere" implies that there is somewhere that isn't included. Where is that?
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There's a very definite hierarchy of precision and strength of lawfulness in
Re:Correction (Score:4, Interesting)
There is no scientifically valid way to rule out life forms which are unlike our own
1) Life will require energy flow. More fully, life will operate much like a heat pump tapping energy flow between a high entropy or temperature sink to a lower entropy or temperature sink.
2) Life will require an environment it can survive in. This story attempts to address part of that with the idea of climate buffering.
3) As K. S. Kyosuke noted in his reply, life will require some matrix capable of the complex morphological structures and behaviors that life will need to survive.
4) Life will need time or a shortcut (like a creator) in order to develop. Evolution-based life will need time (measured in generations) for adaptation to occur.
For example, let's take an isolated "rogue planet". First, it's an object massive enough to round itself under the force of its own gravity, but not massive enough to undergo fusion. Second, it's not orbiting a star and basically is slowly cooling down to the temperature of the cosmic microwave background (no external energy inputs of note). The driver for any life would have to be heat flow from the interior due to heat of formation and possible radioactive decay. The situation is contrived (but in a way that actually probably appears billions of times in nature, just in our galaxy) so that there is no other means to provide significant energy flow to the system.
Restriction 2) is rather simply solved since the environment is very stable over billions of years (unless the rogue planet happens to get too close to a star or runs into something).
Restriction 3) requires either complex chemistry (from elements other than hydrogen or helium) or structure from say possibly, the interaction of different phases of metallic hydrogen and electromagnetism at the core of a gas giant.
Restriction 4) means that if it's evolution-based life derived from abiogenesis, then it needs to be in a high enough energy flow over large enough volume so that enough generations can pass to evolve to a state where they can technically qualify as life (such as traits/information passed from past organisms to future ones). We don't know how big that would need to be, but bigger and older is better. Similarly, we would need the presence of complex structures, which are more likely in a high energy flow environment (eg, amino acids created by weather-induced lightning).
If it's creator-derived or evolved elsewhere and migrated, who knows. The resulting organism might be able to fuse deterium and/or helium 3 isotopes, for example. That allows for creation of higher weight elements too.
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The same as when people say "but why aren't we searching for life which is unlike us", the answer becomes "because we don't know how". There's no basis on which to conclude anything other than "well, we couldn't live there".
The answer is we are. It's called SETI. Whether it's a useful means of carrying out that search is another question.
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Re:Correction (Score:4, Insightful)
Oh yeah, what if they're tasty? Some Cerulian maple-bacon pig or something. ;-)
But, more importantly, if we find life on another planet (or wherever), of any form, intelligent or not, that in and of itself would have a huge impact on life here even if we couldn't get there.
Because the answer to "is there life anywhere else" will have been answered, and the people who loudly say there is only life on this planet will be proven wrong.
And, if we know there's like here, and then confirm there's life elsewhere ... given the size of the universe, you would more or less have to conclude that life is pretty widespread.
Even if it was unintelligent, the discovery of life elsewhere in the universe would be utterly monumental in a lot of different ways.
To me, I don't think you can overstate just how big of a deal that would be. Because it would be a complete game changer in a lot of ways, and lay rest to the notion that Earth is singularly unique in that regard.
I just don't see such a discovery having 'no impact'. Not even a little.
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Admittedly I am more of a critic of how people will react than a predictor of it. Many people still see landing on the
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Well, for starters if we discovered a convincing atmospheric evidence of life then I would bet that launching a gravitational-lens telescope for a closer look would become a major priority. Even it if could only resolve planetary surface features to a few meters the spectroscopic data alone would provide enormous amount of information, including a *lot* of information on the specific local biochemistry. A great deal of the science we're only beginning to do on our own planet thanks to orbital monitoring
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How so? What did it accomplish or change?
There's more than a touch of irony in military project that reached the ultimate high ground only to show us that the world domination game was not worth playing.
But I guess you had to be there to really grasp the significance of Apollo's role in the cold war. Personally I think the 1968 "earthrise" photo from apollo 8 was the most significant contribution, it's often credited with igniting the environmental movement (along with the book "Silent Spring").
The notion of the "pale blue dot" (google it) c
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And, if we know there's like here, and then confirm there's life elsewhere ... given the size of the universe, you would more or less have to conclude that life is pretty widespread.
Would you? You really wouldn't until you found life far away, unless you found a way to conclusively rule out panspermia.
Re:Correction (Score:5, Insightful)
I wish I had mod points. Every time I hear about planets not being able to support life, this is my first thought.
And every time a story about extraterrestrial life gets posted on Slashdot, several dozen people say exactly the same thing, as if they've had some brilliantly original insight that the scientists researching the subject missed. No one is explicitly ruling out the possibility that there are gaseous lifeforms living in the clouds of gas giants, or silicon-based rock monsters like the one in Star Trek. Hell, it would be a huge discovery if we found something like that. But since we're presently incapable of observing such lifeforms firsthand, and have no idea what we should be looking for at a distance of light-years, we have to settle for looking for the planetary "signatures" of temperature, oceans, oxygen content, etc. It may not satisfy the pedants, but it's still extremely difficult by itself. When we're capable of actually exploring other solar systems directly, then maybe we can start to look for fantasy lifeforms on frozen airless rocks and methane clouds.
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No one is explicitly ruling out the possibility that there are gaseous lifeforms living in the clouds of gas giants, or silicon-based rock monsters like the one in Star Trek.
Actually, we know almost all basic chemistry, and the range of (stable) molecules that silicon can form is orders of magnitude less than for carbon.
There is a lot of silicon to be found on/in the surface of our planet (over 900 times more than carbon), and yet lifeforms here didn't integrate it in their core chemistry. At most they used it to reinforce surface/skeletal structures.
It also doesn't readily form gaseous molecules like carbon does (CO2), which would help in energy cycles.
Re:Correction (Score:4, Insightful)
Actually, we know almost all basic chemistry, and the range of (stable) molecules that silicon can form is orders of magnitude less than for carbon.
Well, yeah, but I didn't want to offend the pedants even further. Unless the laws of physics (and therefore basic chemistry) are very different elsewhere in the galaxy, it's not unreasonable to think that carbon-based, liquid-water-dependent lifeforms are the most probable. In fact, I'd be willing to bet a tidy sum of money that the overwhelming majority of unique forms of life are not terribly dissimilar from ours as far as the underlying chemistry is concerned. They might be fantastically alien in all sorts of other strange ways, but they'll still be based on simple organic polymers. But this is still irrelevant to the discussion at hand, because even if there were different forms of life, we have no idea how we might detect them at astronomical distances.
Looking for life (Score:2)
It'd help a lot if the life we're looking for feels like broadcasting really, really powerful modulated EM signals, directed mostly at likely habitats for other life (namely, us.)
--PM
Extremophile (Score:3)
Extremophile [wikipedia.org]
I'm thinking more along the lines of "Life that will use radio signals (or similar) to communicate in such a way that we have a chance of detecting them without either of us leaving our solar systems".
But that's a bit wordy.
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There's a couple things here:
1. Extremophiles evolved progressively to more difficult ecosystems. They came from organisms that could manage in chemically unreactive of mostly water/salt water. It's unlikely the precursors to life, like prions or unbound mRNA chains would've "made it" in arsenic lakes or boiling lakes. But some prokaryotes could manage in environments with a little arsenic, and evolution could work its magic.
Like the creationists say, getting something as complex and robust as a modern
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2. The utility of radio waves for communication wouldn't hinge much on the physic form of an organism, just something much like sapience.
Radio waves don't reach very far before they are drowned out by natural sources of radiation. Beyond one light year, you already need powerful radio sources, combined with large antennas to detect them. And there's only a short time window. It took earth billions of years before we started emitting radio waves, and already we're reaching the end of the window with the increased use of wide spectrum digital transmissions that are much harder to detect from a distance.
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Also, efficient data transmission is indistinguishable from noise if you don't know the protocol.
It's worth noting, however, that the SETI program only ever really looked for explicit beacons from alien civilizations, hence why they picked the radio frequency of positronium spin flip (and other similar frequencies from fundamental physics).
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We don't even know for sure that it arose on this one. Panspermia could easily have spread the seeds of life throughout our galaxy, in which case the relevant question is how hospitable is the planet to the sorts of extremophiles that could survive the journey? And how genetically diverse and evolutionarily flexible is the life that survived the trip, especially in regards to stabilizing and fertilizing the planetary ecosystem it finds itself in?
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"Vital For Possibility of Earth-like Alien Life"
A lot of assumptions there.
We can't even communicate with other species here on Earth in the same Class as us. Elephants, whales, and dolphins show signs of intelligence. Certainly enough to communicate with each other. And we've hunted species of two of them to the verge of extinction. The Great Apes are in the same Family as humans and we can't have a meaningful conversation with them. Perhaps they are simply too primitive. Or maybe we aren't as smart as we would like to believe.
A non-terrestrial species may communicate using some
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The Great Apes are in the same Family as humans and we can't have a meaningful conversation with them.
Depends on how you define that. We know a bit of the vocalized language of some apes, but one problem here is that within one species there is no single, unified language.
It's the same with humans: I can't have a meaningful conversation with a Chinese person in Cantonese (and have little doubt I ever will). Even two random Chinese likely don't understand each other, since there are so many dialects.
But despite this, we have successfully communicated with apes that were reared from infancy. They seem to unde
Swampland! (Score:4, Funny)
This makes sense. The University of East Anglia exists in swampland that is slowly sinking while the sea is slowly rising. It's halfway to ocean already.
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Maybe yes, maybe no.
We know that life has started out in an anaerobic environment with water present. Everything else is up for grabs. So if you're looking for life-as-we-know-it, it makes sense to go with the conditions we already know works.
TF Headline is, of course, hyperbolic. Alien life doesn't necessarily require conditions similar to earth. But that's were the money is. If you have limit the types of planet systems you will spend the time and money to look carefully at, you just might go with wh
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And how would you recommend we look for life of a kind we have no understanding of? We're still trying to figure out how to detect life-much-as-we-know-it if it's not jumping up and down and screaming (metaphorically of course). An example of a much easier problem: Suppose I know with absolute certainty that there's a specific thing in the room with you. Given only that much information, do you suppose you can identify it? Now identify the other specific thing that I suspect is also in the room. That's
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LIFE may originate on some planet where Methane, Hexaine or Helium is the local liquid, or molten Lead, Carbon or Iron, or, or, or...
Chemistry.
Carbon is probably where it's at in terms of a backbone that allows for enough complexity, and that puts some limits on temperature and other parameters.
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Actually, there's some argument that tidal flats were important in the evolution of early life, as were the amplified plate tectonics (life probably evolved around underwater volcanic vents. Not to mention the fact that having a large moon kneading the planet has dramatically slowed the cooling of the core, maintaining a strong magnetic field for far longer than would otherwise have been possible. Which in turn allows an atmosphere to be retained. Mars has plenty of gravity to retain an atmosphere, and i
Such like won't have technology (Score:2)
Why?
No flint tools or fire. Ergo, when we get there we can eat them!
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H2O is a pretty awesome and creepy molecule. and has some pretty important properties that make advanced chemistry easier.
Not on Arrakis (Score:2)
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> BTW, if you averaged all the elevations on earth, none of it would be above the level of the ocean.
This would be true of any planet with any amount of surface water.
Given a perfect sphere, the water is just going to spread out and cover it.
You can't go around leveling the land without impacting the water level. They are linked.
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This would be true of any planet with any amount of surface water.
This statement isn't true. The rest of your statements are true.
Consider a perfectly spherical planet with no surface water, but with an underground water supply not too far below the surface (eg. as Europa is hypothesized to be).
Now make it less smooth, eg. slam it with meteors such that there's no net loss in matter (possibly a slight net gain), but it's no longer perfectly smooth.
Now you have surface water on a planet with an average elevation higher than the water level.
Basically, any planet with surfa
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That's why I said surface water.
My statements wouldn't apply to a realistic scenario with underground water.
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Yup.
From what I've read, it seems that plate tectonics have something to do with bringing water to the surface, so it might be a more co-dependent relationship between P.T., oceans and continents.
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Actually if I remember my Dune correctly water was once plentiful on Arrakis, but was locked away deep underground by the larval sand trout in order to provide a more hospitable environment for their adult form, the sand worms.
Also, if plate tectonics stops that means our planet's core has cooled to the point where it can no longer provide a strong magnetosphere, at which point the solar wind will begin stripping away our atmosphere, boiling away the oceans in the process as the air pressure drops, and leav
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Venus is a counter argument to the idea that without plate tectonics and/or a strong magnetosphere the atmosphere would be stripped away. At that some theorize it is the plate tectonics (and life) that remove carbon allowing our atmosphere to be as thin as it is.
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Fair point. In fact while confirming it I came across the fact that Earth is actually losing atmosphere to space faster than Venus - something that appears to rather harshly conflict with our theories on the subject.
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It's complex. Note that Venus has lost most of its hydrogen and like the Earth, its helium. For the Earth, much of the atmosphere losses is probably hydrogen liberated by photo-disassociation of water which is where much of our hydrogen is tied up. Heavier molecules such as CO2 get held by gravity.
One future scenario for the Earth is to become Venus like, perhaps as soon as a billion years. The Sun gets hotter over its lifetime due to increasing percentage of helium from fusion increasing density, eventuall
Garbage in, garbage out (Score:2)
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What?
First of all, there are more than three phases of matter. A molecule in plasma state, despite being far apart from its neighbours like gas, interacts easily with them like liquids.
Second, "too far apart" is not well-defined or proven.
Third, "molecules aren't moving" isn't true of a solid object, nor have you shown why that's necessary for life.
The life forms we are most familiar with happen to include aspects of all three phases (no plasma aspects in any life form I know of). The artificial things we
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Some crystals also have some of the qualities of life
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Actually, the problem with a gaseous environment is not that the molecules are too far apart - in fact you get a (very roughly) comparable frequency of collisions, and they're at higher energies which make reactions more likely. The problem is that as larger molecules form they tend to precipitate out of solution, and in a gas there is insufficient buoyancy to keep them mobile once they've done so. On Earth life likely evolved within the primordial open-faced sandwich on the bottom of tidal pools, borrowi
and with that insult (Score:1)
Oh, *that* UEA! (Score:2)
I thought maybe they'd branched out in a totally unexpected way.
Limited Imagination (Score:2)
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Because complex chemistry is a prerequisite for life. There's a reason organic chemistry (carbon-based chemistry) is it's own topic--it's extremely complex.
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Of course, almost none of the thousands of other species on Earth look exactly like us,
Exactly? Come back here with those goalposts. Creatures here have eyes above nostrils above mouth for a reason; likewise, they have head above body (at least in some positions) for a reason. The mouth is at one end, the ass at the other. If it were advantageous to have these features somewhere else, they might well. For anything which meets our definition of life, it's reasonable to imagine that they would take on a similar form.
Neil DeGrasse Tyson (Score:4, Interesting)