Billions of Habitable Planets? 479
cbv writes: "MSNBC has an interesting article about new calculations by Charly Lineweaver and Daniel Grether, both of the University of New South Wales in Australia, which provides an interesting answer to the question on how many potentially habitable planets exist in our galaxy."
Did they remember to subtract 1? (Score:5, Insightful)
Because by the time we can find another one that is, this one won't be.
--Blair
"Keeping up with the Gbrtlrxzes."
Re:Did they remember to subtract 1? (Score:2)
Its the next leg of evolution, where we actually manage to amble our way across lightyears to get there. THAT... may take a significant fraction of the rest of civilization as we know it. And while it may take thousands of years to make that next huge step, the planet will be around for billions more yet.
-Restil
Cute, but false. (Score:5, Interesting)
By "habitable" they mean planets like Mars and Venus. Places you can live on in extremely well made air-tight shelters, and maybe eventually terraform.
We could have a sustained nuclear war (presumably sustained from off-planet), stripping the planet of sophisticated lifeforms and blowing off half of its atmosphere, and it would still be a nicer place to live than anywhere else in our solar system or anything we're likely to find orbiting another star.
In terms of human habitability, we're taking pretty good care of this one. Wiping out the wilds is sad, but a choice of farms or forests is easy for hungry people. Where it appears unnecessary, done too casually for convenience rather than survival, that is just staying ahead of what the population growth will demand in a generation or two. The pollution looks bad, but it's a feature of short-lived transitional technology, and will tail off before intolerable damage is done.
On the whole, human effort is greatly increasing human habitability of Earth, not decreasing it. The pristine, wild world of a hundred centuries ago couldn't support half a billion humans, while today it supports well over 6 billion, and the way is being made for 10. Even one century ago, it probably couldn't have sustained half our current population. Things probably won't get tight here on Earth's surface until at least 100 billion, by which time we'll be seriously working on these other places to live. As it is, we haven't seriously dented the resources of our planet, just dug around a little at the choice bits on the surface.
The BIG question (Score:3, Interesting)
Re:The BIG question (Score:5, Funny)
Re:The BIG question (Score:3, Informative)
We appear to be waiting for a crisis, wherein the surface of Earth is sterilized by a marauding enemy. We'll then live underground long enough to retrofit the Yamato as a space battleship, and send her and her brave crew out as the last hope of mankind.
We just need to find ourselves a good Avatar (Score:2)
Re:The BIG question (Score:2, Insightful)
Re:The BIG question (Score:5, Interesting)
Manned interstellar spaceflight would require:
Some have observed that the level of committment this would require of humanity would be like nothing ever seen before, and which would require devotion that has historically only been commanded by religious quests.
Follow-up question (Score:2)
(Of course, I'm asking this because nobody is going to devote such resources and focus on one far-off goal long enough to accomplish it; anyone who does will lose other competitions to groups which do not. On the other hand, if the goal can be accomplished via a number of short-term projects each of which is useful and even profitable in its own right, the grand goal follows almost inevitably.)
Re:The BIG question (Score:3, Funny)
require devotion that has historically only been commanded by religious quests.
Fortunately, there's a "religion" with the right kind of funding to do so!
Who would ever think something good would come out of Scientology?
you mean... (Score:5, Informative)
Where,
N = The number of communicative civilizations
The number of civilizations in the Milky Way Galaxy whose radio emissions are detectable.
R* = The rate of formation of suitable stars
The rate of formation of stars with a large enough "habitable zone" and long enough lifetime to be suitable for the development of intelligent life.
fp = The fraction of those stars with planets
The fraction of Sun-like stars with planets is currently unknown, but evidence indicates that planetary systems may be common for stars like the Sun. more info
ne = The number of "earths" per planetary system
All stars have a habitable zone where a planet would be able to maintain a temperature that would allow liquid water. A planet in the habitable zone could have the basic conditions for life as we know it. more info
fl = The fraction of those planets where life develops
Although a planet orbits in the habitable zone of a suitable star, other factors are necessary for life to arise. Thus, only a fraction of suitable planets will actually develop life.
fi = The fraction life sites where intelligence develops
Life on Earth began over 3.5 billion years ago. Intelligence took a long time to develop. On other life-bearing planets it may happen faster, it may take longer, or it may not develop at all. For more information, please visit Dr. William Calvin's "The Drake Equation's fi"
fc = The fraction of planets where technology develops
The fraction of planets with intelligent life that develop technological civilizations, i.e., technology that releases detectable signs of their existence into space.
L = The "Lifetime" of communicating civilizations
The length of time such civilizations release detectable signals into space.
Re:you mean... (Score:5, Informative)
Re:you mean... (Score:3, Funny)
Bah.
The answer is easy, 42. It's nice you finally found the question.
Re:you mean... (Score:2)
It may well be that most civilizations go through a brief broadcast period and then learn to use point-to-point methods of communication that aren't easily detectable. One reason is simple economics: dumping energy into space is wasteful. But it may also be that successful civilizations actively avoid broadcasting their presence to avoid hostile encounters.
Here's a depressing thought: they may also consider it prudent to quickly destroy nearby infant civilizations quickly, perhaps by accellerating small chunks of rock to near lightspeed and aiming them at noisy planets. Such an attack could obliterate life on earth with virtually no warning at all.
Re:you mean... (Score:2)
(mod: -1, Silly
Re:you mean... (Score:5, Interesting)
One of the problems that the Drake Equation produces is that if you take reasonable (some would say optimistic) numbers for everything up to the average duration of technological civilizations, then you are left with three possibilities:
1. If such civilizations last a long time, "They" should be _here_ (leading either the the Flying Saucer hypothesis---they are here and we are seeing them, or the Zoo Hypothesis---they are here and are hiding in obedience to the Prime Directive, which they observe with far greater fiqdelity than Captain Kirk could ever muster). -or-
2. If such civilizations last a long time, and "They" are not "here" then it becomes necessary to explain why each and every technological civilization has consistently chosen not to build starships. The first civilization to build starships would spread across the entire Galaxy on a timescale that is short relative to the age of the Galaxy. Perhaps they lose interest in space flight and building starships because they are spending all their time surfing the net. (Think about it---the whole point of space flight is the proposition that there are privileged spatial locations, and the whole point of the net is that physical location is more or less irrelevant.) -or-
3. Such civilizations do not last a long time, and blow themselves up or otherwise fall apart pretty quickly (... film at 11). Thus the Drake Equation produces what is called the Fermi Paradox (i.e., "Where are They?"), in that the implications of #3 and #2 are not terribly encouraging to some folks, but the two flavors of #1 are kinda hard to come to grips with.
An alternate version of 2 is that interstellar travel is far more difficult than we think it is. Right now, it doesn't seem much beyond the boundaries of current technology to launch "generation ships," which power systems. An
alternative is robot probes with artificial intelligence; these don't seem so difficult either. The Milky Way galaxy is well under 10^5 light years in diameter and over 10^9 years old, so even travel beginning fairly recently in Galactic history and proceeding well under the speed of light ought to have filled the Galaxy by now. (Travel very near the speed of light still seems very hard, but such high speed isn't necessary to fill the Galaxy with life.) The paradox, then, is that we don't observe evidence of anybody besides us.
Re:you mean... (Score:2)
Too bad discussions on Slashdot die so quick. This one could have been fun!
Short lived civilizations could be good, not bad (Score:5, Insightful)
Or alternatively, civilizations progress at a geometric rate, transcending themselves in a few short generations, so that by the time intersteller travel becomes feasable they have lost interest and moved on to more compelling possibilities (perhaps departing this frame of reference entirely).
Once one hypothesizes a civilization significantly more advanced than our own it becomes difficult to even imagine the technologies they may have, much less what interests they would find compelling, or what goals they might set for themselves. For all we know they are all around us, unrecognized because they operate at levels as far beyond us as we are beyond the simple microbe.
Re:Short lived civilizations could be good, not ba (Score:3, Interesting)
We'll eventually be able to create our own "virtual" universes, which are infinitly more interesting, since WE'RE effectively Gods there.
If I had a choice between a) slowly trekking through one boring physical universe, or b) freeing my mind from its limited primordial wetware brain, and moving into my own universe(s), I'd choose the latter. [aeiveos.com]
--
Re:Add one more factor the the calculation (Score:3, Informative)
Re:Add one more factor the the calculation (Score:2)
I'm not sure that was actually considered when the Drake equation was put together. "L" assumes that a civilazation made it to broadcasting - or better yet colonization.
Just another factor to consider -
Re:Add one more factor the the calculation (Score:2)
Re:Add one more factor the the calculation (Score:3, Interesting)
Smallpox and the bubonic plague are real killers, but not civilation-killers. The Black Plague killed somewhere between 1/4 and 3/4 of Europeans in less than a century, but European civilation not only survived but thrived. The survivors were richer and more willing to look at new ways of doing things. Especially, the shrinking workforce forced craftsmen to look at labor-saving devices -- for instance, ironworks replaced much manpower on bellows and hammers with waterpower, and in a few decades were making more and better iron than ever before.
The early course of smallpox in Europe is not too clear, but it is clear that there were centuries when it was simply accepted that at least 50% of each generation would catch it, and over 25% would die. All it meant was that fewer peasants had to starve to death or be hanged for theft, and there were more chances for peasants to become middle class or middle class to become noble...
In north america, a whole cluster of European diseases swept through a native population with no immunities. (There may have been some deliberate attempts at germ warfare like giving away smallpox-infested blankets, but the diseases were spreading so fast on their own that it hardly mattered.) Sometimes these diseases wiped out an entire tribe in one year, when the tribe was camped in one village (and probably not eating very well either), but other (maybe better fed, or more dispersed) tribes were only lightly hit. Possibly smallpox killed up to 75% and measles, etc., brought it up to 90% on the average. That didn't end most of their cultures -- it just made it a lot easier for white men to shoot and drive off the survivors.
It is highly unlikely that any one disease will ever kill more than 75%. And a real civilization can survive that quite well. There's considerable disruption in deciding how to scale back businesses to the smaller work force and customer base, but the problems are buffered by all that inherited wealth...
I claim this planet in the name of ... ME! (Score:2, Redundant)
Re:I claim this planet in the name of ... ME! (Score:2)
From this website [leaderu.com]
Celestial (Heaven) - for Mormons who have kept ALL of the laws and ordinances of their church. What will the celestial heaven (kingdom) supposedly be like for a good Mormon? He will be a god, he will rule over a planet with his wives and spirit children.
laugh, its a joke
this is a WAG, nothing more, nothing less. (Score:4, Insightful)
But experts attribute these findings to the limitations of technology. "
Hmm, WAG anyone? Wild assed guess for those that are AC (Acronmyn-Challenged).
I would bet a terabyte of New Zealand Sheep porn that tomorrow there will be 500 stories debunking this. More "proof by way of media" sounds like to me.
I loved this comment:
'?Our solar system is Jupiter and a bunch of junk,? as Lineweaver puts it.'
Yeah baby, I live on a hurling mass of yesterdays dinner and some junk mail....wohooo.....
Re:this is a WAG, nothing more, nothing less. (Score:2)
More properly, a SWAG. You seem to have acronyms on the brain, so you can figure that one out.
I think the real question is this: why the heck do you posess terabytes of sheep porn?
Re:this is a WAG, nothing more, nothing less. (Score:2, Interesting)
True. And as for habitability, has anyone considered the importance of plate tectonics and tides for life? Or the possibility of a causal relationship between massive collisions early in a planet's existence, and extended periods where plate tectonics continues?
Compare Earth, Venus, and Mars:
Venus: Probably no massive collision early in its life. Boring world, no way for CO2 to be recycled into a big liquid water carbon sink. Looks geologically-dead.
Mars: A mostly-geologically-dead world, too small to retain much of its original heat, and, of course, no massive collision early in its life. Had liquid water once upon a time.
Earth: Smacked by a Mars-sized impactor early in its life. Debris coalesced to form huge satellite called "the Moon". Frighteningly geologically-active. Big-ass oceans sink lots of CO2. Plate tectonics keeps it underground rather than letting it vent into the air.
A sample size of "three" is pretty slim, but to my (untrained - any exogeologist-types out there care to comment?) mind, the facts that Earth got whacked and the fact that the Earth still has a thin crust (while Mars, and more interestingly, Venus, have cooled off) appear to be more than coincidence.
Bring in an exobiologist -- perhaps "tides" (think "tidal pools" are handy for forming life. Also think about the impact that tectonic activity (and life) has in recycling CO2 on Earth.
Does anyone know if Earth's core is "too hot" to be accounted for simply by heat from 4.5 billion years of radioactive decay of its initial components?
I'm speculating that the impact that created the Moon also added a metric buttload of heat to the still-forming planet's core, while simultaneously stripping the proto-Earth of some of its lighter silicates. If the impactor came from "far enough away" in the solar system, it may have brought a metric buttload of water ice with it. The result was a glob of metal-enriched rock, water, water, everywhere, a double-planet system with tides (useful for future development of life) and recycling of crustal material via plate tectonics due to the planet's thin crust.
(jumping off the deep end into wild-ass speculation now...)
Perhaps this is another reason to go to Pluto. Perhaps the Pluto/Charon system formed in a manner similar to Earth/Moon. If we found evidence that Pluto had a metallic core, and that it was warmer than could be accounted for by radioactive decay...
If we assume (or can demonstrate) that things like plate tectonics and tides are "good" for the formation of life (at least, they seem "better" than the situations on Mars and Venus that arose from the lack thereof), it'd be nice to know that early massive impacts were common. It'd be even nicer to know that there was a correlation between such impacts and "warm" planets with lots of water.
(Sigh... still holding out for the day we see the spectrum of light reflected from a rocky planet in orbit around another star... a spectrum showing lots of oxygen that should have reacted itself away by now unless something on the planet's surface was replenishing the supply...)
Metrics... (Score:3, Offtopic)
Re:Metrics... (Score:3, Informative)
Re:Metrics... (Score:5, Funny)
Can anyone tell me the difference between a 'metric buttload' and an 'Imperial buttload'? Thanks.
I believe the imperial buttload is based on the size of Hing Henry V's rear end. Quite large, it was.
While the metric buttload is smaller, it scales nicely. For example, there are 10 metric buttloads in a metric shitload.
QED
Re:this is a WAG, nothing more, nothing less. (Score:2)
The Moon isn't a remnant of the original impactor, it coalesced from debris thrown off after impact.
D00dz with a hell of a lot more computing power than I have have done computational fluid dynamic simulations of an off-center impact of a Mars-sized impactor on a mostly-molten proto-Earth with a bunch of silicates floating on top of a more dense core.
The most common result is that the two bodies coalesce, but with a lot of crap (particularly from the upper, silicate-enriched layers of proto-Earth) thrown into orbit.
That is, what we see today, namely an Earth with lots of metals, and a silicate-rich moon.
(This makes sense -- the competing theory to the impact theory is that the Earth and Moon formed simultaneously out of the same accumulating cloud of dust. One of the reasons this theory has been deprecated in favor of the impact theory is that it doesn't account for the mineral differences between Earth and Luna.)
Re:this is a WAG, nothing more, nothing less. (Score:2)
Re:this is a WAG, nothing more, nothing less. (Score:4, Funny)
I'm more interested in that terrabyte of NZ sheep porn, myself...
Why live on planets? (Score:2, Interesting)
Re:Why live on planets? (Score:2)
After all, why invest all the time and resources and everything to build a floating planet?
There's already one there, why not use it?
My money is going to be more on habitat controls than planet-sized space stations.
Here's what I see as a more likely scenario:
We find a nice planet to inhabit, pick out the most strategic locations for civilization hubs, send in teams to build the hubs, and slowly expand the hubs as people come in.
So to sum up:
We're probably going to colonize planets one at a time, and live on a solid, natural surface. We are not going to build a zillion death star type space stations and live life zipping around the cosmos.
but hey, I'm always up for a debate...:-)
Re:Why live on planets? (Score:2)
Re:Why live on planets? (Score:3, Interesting)
Maybe if the planet is earth-like enough that you can just land, go outside in your T-shirt, pitch a tent and stay the night, it'll get colonized. But there isn't much point if you have to do any serious work, like, say, replacing a reducing atmosphere or getting more water from somewhere.
Re:Why live on planets? (Score:2)
Re:Why live on planets? (Score:2)
Just because resources are free, does not mean they ar eunlimited. There is a finite amount of bas emetals in the earth, such as iron and soforth. Removing enough to construct the space stations you describe (enough to hold a planet's worth of people) would require the resources of more than one planet.
Re:Why live on planets? (Score:2)
Re:Why live on planets? (Score:2, Insightful)
Re:Why live on planets? (Score:2)
Re:Why live on planets? (Score:2)
Technically, I'm sure you're correct. By the time we are able to travel to other planets, they will probably not be a necessity; but what a bleak picture of life that presents.
I guess I have too much affection for sunrises, rivers, mountains, cool breezes, etc.
Re:Why live on planets? (Score:2, Informative)
Gravity.
There are a number of problems with space colonization, but one of the killers is gravity.
But what about oxygen, food, etc you may ask?
Gravity takes care of the containment for you. Your gravity isn't going to spring a leak and start venting air away (assuming it is great enough to hold it in place at a proper pressure).
Further, without physical stress (ie: weight) bones/muscles deteriorate requiring more maintanence to keep the human colonists functional.
Food: A planet provides a MASSIVE surface area with which to grow crops (even if the soil is unarable, large hydroponics systems could deal with it). A self sustaining station would require massive amounts of materials to make a farm large enough to feed its inhabitants. Let alone if a small asteroid came along and broke the ceiling out of your greenhouse...
Assuming you aren't eating nutritional pills by then.
Re:Why live on planets? (Score:2)
Planets have more available resources than space stations.
Planets with a proper ecosystem naturally recycle the elements needed for life, mainly in our case, Oxygen and water.
While a 6 mile wide asteroid can cause serious damage to both space stations and planets, planets are pretty damn impervious to baseball sized rocks (of which in space there are many many more) where space stations can be quite devestated by them.
The magnetic fields and atmosphere of planets filter out a lot of dangerous radiation which space stations need to take special care with.
Planets aren't going anywhere quite yet I feel.
-Restil
Old Hat (Score:3, Interesting)
The only original take is that those 'one percents' are getting replaced with percentages actually based in reality.
Speculations like this used to be popular because astronomy was nowhere near the technology needed to actually see planets out there. If I remember correctly, the first true proof of planets around other stars occurred around 1995 when these first gas giants started to be detected.
With the detection methods getting better every year though, it's only a matter of time before we can directly detect terrestrial sized planets around other stars. That's the point where these statistical guesses get kind of silly.
"I bet there's a thousand planets out there!"
"Actually, there are 1422. We can just count them now."
stipe42
www.pcwatch.com [pcwatch.com]
more than half (Score:5, Funny)
Being out in BFE helps too... (Score:2, Informative)
But maybe not for that reason (Score:2)
Re:Being out in BFE helps too... (Score:2)
The population of the universe is 0... (Score:3, Funny)
Number of Planets in the Universe = infinity
Number of Populated Planets in the Universe = N
n
--------- = 0
infinity
Re:The population of the universe is 0... (Score:2)
Oh well.
“A reasonable guess" (Score:3, Insightful)
How the hell is that a "reasonable" guess? Even assuming the definition of "Jupiters" requires that it be exactly like ours, we can't assume that just because a "Jupiter" forms that an "Earth" will too!
I agree that it is reasonable to assume that a habitable Earth requres a comet/asteriod blocker, but the presence of a Jupiter does not imply the presence of an Earth.
Asimov (Score:3, Interesting)
why are we always the primitive society in sci-fi? (Score:2, Interesting)
How many? (Score:4, Funny)
...Billions and Billions...
</sagan voice>
Boy, I'll miss that guy! One of the many people who triggered lots of tech interest in me and made me who I am!
High estimate... (Score:2, Insightful)
So in short, I think this guy is nuts to suggest billions of earths. Maybe millions (tens or hundreds) in the venus->mars range but not billions.
Re:High estimate... (Score:2)
I suppose it depends on what you mean by "intelligent". Dinosaurs were intelligent, so were mastadons, so are dogs and cats and gorillas and birds. If you mean intelligent as in technologically adept as human animals are, there is no reason to assume that there are a lot of those.
If it were not for an accident 65 bya, there would be no humans and dinosaurs might well STILL have run of the planet. There is NO imperative for technological intelligence or development for that matter. If not for the Europeans coming to the North America, the native Americans would still be quite healthy and happy living as the always had - they had no technological development beyond what was necessary and useful to them. The Commanche were not technologically superior to the people of Mesa Verde/cliff dwellers simply because they came later. I am not in any way dissing native Americans but am simply making a point...if not for the Europeans with THEIR accidental technologically-based society coming to North America, the natives would most likely STILL be living as they have for hundreds of years.
So, there may well (and likely is) many habitable planets. There is likely MANY locations with some form of life. It does NOT follow that there must be lots and lots of technologically advanced societies. A few here and there, perhaps, with an unknown fraction of those killing themselves off due to war or polluting themselves out of a home, with the survivors being few and far between.
That said, there is no reason to assume a priori that they would be any better about space exploration than we are. It is COSTLY to go into space. It is especially costly to put people into space. It is EXTREMELY costly to colonize space. I would also doubt that there is any spiffy way around basic rules like lightspeed barriers, etc, so it is not even a given that their spacecraft, robotic or not, can get very far in any reasonable amount of time. There is no reason to assume that machines can ever be produced that would be so much better than living things at self repair (EVERYTHING makes mistakes and they are usually detrimental - evolution isn't as simple as saying "machines will make mistakes self-replicating in a way that will permit evolution to occur there too). So some technical society launches a probe to a nearby star. Maybe it gets there within a reasonable amount of time so that those back home are still willing and able to listen to its transmissions back. Maybe they launch it and then collapse and the whole project was moot. Maybe they go for a while, expand a little within their solar system and then slowly crap out...millenia before WE came along. We just missed them by a few thousand years.
The real possibilities are endless and at least some of what I am stating here addresses the Fermi Paradox (which is, of course, itself based on the false assumption/conceit that advanced intelligence means technology which means space travel, etc). Dinosaurs, et al, were HIGHLY intelligent and advanced compared to cyanobacteria. They were HIGHLY advanced and intelligent compared to virtually everything that came before (and many that came after).
There is NO technological imperative in biology/evolution.
Puh-leez! (Score:3, Funny)
It doesn't take a genius (just a bit of open-mindedness) to figure out that in the vast reaches of just our own galaxy (not to mention the universe) the chances are good that additional systems similar to Sol were formed.
Remember: The absence of proof is not the proof of absence.
On a lighter note, I really hope they'd hurry up and colonize another planet. Then, next time some ecologist gets on my nerves by saying: "THINK OF THE PLANET!" I can retort: Sheesh, it's not like it's the only one we've got!".
And yes, I know I stole that from Futurama
This has probly already been said, but... (Score:2, Funny)
Anyone who believes that a "god-like being" would only create life on a singular planet is even more arrogant.
Anyone who believes that we will be able to easily find them within the next century is naive.
Anyone who thinks that people will be sent to any such planets found within the current century is a tool.
Remember, the earth is not the center of the universe (unless of course, all points in the universe are equidistant from every other point, then every point is the center of the universe, which would really mean it has no center. But what are the odds of that...).
That being said... I wouldn't mind taking a ride on a monkey fueled liquid nitrogen cooled rocket sleigh to some far off planet and get it on with alien chicks with 2 bellybuttons, like William Shatner.
Re:This has probly already been said, but... (Score:2)
Really, it is annoying.
Jupiter-like planets offer 2 chances for life (Score:5, Interesting)
The moons of the Jupiter-like planet offer another possibility for life. Like Europa, gravitational stresses from orbiting such a large planet can cause heat to warm up a normally frozen world. This heat might help melt ice into water (as is thought to be on Europa under the ice shell). And where there's water, life might not be far behind.
Now this isn't to say that life=intelligence. We might be talking about the ET equivalent of bacteria, here. Still, the discovery of ET-bacteria would be a huge matter.
Hadn't we better lie low? (Score:2, Insightful)
Frankly, I've always wondered why the rush to find other civilizations. Unless we confidently expect to be able to do to them what Cortez did to the Aztecs, I think the best idea is to hope the Earth stays hidden from prying eyes. Afterall, we may be Aztecs to them! And since when has a lesser civilization benefitted from meeting a superior one?
before you go bonkers about this (Score:3, Interesting)
If there are aliens, where are they?
Sounds silly? I agree. Sounds like "The Fermi Paradox" is too fancy a name for a natural objection? I agree on this too. However, when you think about it, it becomes fairly obvious that it really is the only argument in this debate that is somewhere between strong and very strong.
Answer: Not much further along than we. (Score:2)
Radio signals? How should we send, what solar systems, what frequnencies, what intensity, what signal type? Likewise goes for listening. SETI is looking at one extremely small area of the sky, and yet it needs an extremely powerful signal, only the most powerful of radars aiming precisely for earth would be detected. And even then it could be put off as static, or a burst by some natural phenomen.
We could use a Warpdrive and a Sub-space communications system. But some sci-fi isn't going to be sci-fact ever, of course there's no telling which in advance.
Kjella
Re:before you go bonkers about this (Score:4, Interesting)
I don't know if there are any correlaries to this Fermi Paradox, but based solely on your post I think Fermi made waaaay too many assumptions. Lets see...
I could go on forever. I don't consider this a strong argument. I prefer the approach of statistics, even if it can yield no answers based our on current lack of information.
Re:before you go bonkers about this (Score:2)
Either only Earth have a technologically advanced civilization, or many planets do.
It is, in other words, not the case that only "a few" planets have highly developed civilizations. By many is meant at least in the order of a billion or so. I'm sure you can figure out why this premise is not unreasonable for yourself. Now, the argument goes, maybe the objections you raise are valid for some of the civilizations, but it would incredibly naive to think that they (or, to be more precis, at least one) would be for all of them. Even if what you say would be the case for 99% of them, there would still be many millions left.
This is, however, an interesting debate, albeit an old one. Feel free to reply if you think something is seriously wrong with the line of reasoning outlined above.
Re:before you go bonkers about this (Score:3, Insightful)
Perhaps they are waiting for us to grow out of our infancy. I mean, do you really think we're really to handle that sort of idea? Let's take a look a high level look at our planet:
It seems to me any highly evolved race would know well enough to keep their distance and wait to see if we destroy ourselves before initiating contact (especially if they knew, like a wise parent, that we have to figure these things out for ourselves).
habital in what context? (Score:2, Interesting)
Fact is that if there was life on another planet we would not be able to get there with current technology and understanding of physics. It would take to long traveling at what scientists today call the maximum speed limit 'the speed of light'. Maybe someday when we understand space and time better but not now.
Watch Discovery channel now and then as they already went over alot of this stuff. They made a discovery a while ago and discovered how to detect the 'gas giants' as they call them (jupiter / sturn sized planets) orbiting a star by watching the stars wabble.
And for you real space fanatics http://www.spaceref.com/ and www.space.com are great sites.
Lastly I cant type and spell so don't point out my typoes and spelling errors it is really laim.
Re:habital in what context? (Score:2)
To bad! According to current thoery proposed by Einstein, and many of his believers nothing can travel faster than the speed of light and that which does looses mass. The loosing mass part has been proven in lab test as a particle like an electron is accelerated to the speed of light it gets lighter. There have been many who believe that because of this, light is considered the maximum speed limit. Try watching discovery as that is where they mentioned this.
"But that doesn't mean that we will ever necessarily create a faster-than-light mode of transportation."
True, but maybe we'll find a way to bend space or warp time so that we do not need to travel faster than the speed of light, but that we can travel through time by bending space. There have been theories proposed that if you bend space and make two points that are light years apart at the same point in time then you can travel through space in a shorter period of time. It is actually confusing and better explained as if space were a sheet of paper. If you have a hole at two ends of this paper, and this piece of paper, then you fold the paper in half the holes are now much closer and the travel time is near 0 if these holes are next to each other. So the question then becomes is it possible to bend space?
"Not being concerned enough with your post to look at a dictionary or check for typos is also pretty lame."
Sorry my dictionary got stuck up your ass.
New planets? (Score:2, Funny)
Universal Sterilization program (Score:3, Interesting)
Our universe is probably a mere atom inside a larger universe, and these radiation bursts are simply the efforts of their Einstein trying to split us.
Only discusses HABITABLE worlds. (Score:3, Interesting)
Its also fair to wonder, how many spacefaring civilizations are there? By that I don't mean, how many have launched someone into space, but how many have actually colonized worlds outside of their home solar system?
It has been shown, that given extremely slow, but reasonable travel times between stars, and assuming it would take 500 years (for an already technologically advanced society) to develop a world and the rest of the solar system, then advance on to the next one. With this in mind, such a civilization would only require about 3 million years to completely colonize the galaxy. Considering the billions of years the galaxy has existed, 3 million years is but a brief moment in time. If it was going to happen, it would have already happened.
Now consider our own situation. We're 4.3 light years from the nearest star. We're in the perfect location to drop off a few test subjects (humans with no technological knowledge) and see what happens. It would take a long time before they'd discover what really happened. And others could observe and reflect in that time.
-Restil
Re:Only discusses HABITABLE worlds. (Score:2)
That doesn't mean that they always would make the next step. There's always going to be those cultures that decide to withdrawl from the rest of the galaxy and live on their own. But there's no reason it COULDN'T happen in that amount of time.
-Restil
Safety and Security. (Score:5, Funny)
Other factors (Score:3, Interesting)
How many planets of the right size, right consitution, right size and distance and periodicity of large satellites, right distance from sun, right periodicity of solar orbit, right periodicity of rotation, right frequency of asteroid collisions, right strength of magnetic field, right type of sun, right stage of solar lifecycle, right stellar neighborhood (no local supernovae). . .
Seems pretty farfetched to me.
.com flashback (Score:2, Insightful)
The reasoning reminds me
How many people surf the web?
If only 1% of those people come to our site, WomenWithoutBras.com, then, at a $10cpm, we will make 42 billion dollars a month, wow!
Want to buy some stock?
Eventually, when we stop sending astronauts into orbit to monitor mice having sex, and put up some decent astonomical instruments, we will be able to image some Earth sized worlds, and then we will forget all about the statistics.
Rare Earth (Score:3, Interesting)
The Problem with Space Travel (Score:3, Interesting)
Nearest star is just over 3 light years away, so, traveling at 1/10 the speed of light, it would take you 30 years to get there.
1/10 speed of light = 66.9 Million Miles per Hour
Therefore, the problem becomes:
You must somehow build a spacecraft that can travel at 66.9 Million Miles per hour, non-stop for 30 years, and can accomodate a crew for that same 30 years.
Re:It's almost as hard as you say it is... (Score:2, Informative)
No, you dont. You must build a spacecraft that can _accelerate to 66.9 Million Miles per hour, and deccellerate a few decades later.
Once you have picked up speed in space there is no additional effort to keep it, since there is very little friction in the near-emptyness of space.
You are right about one thing though.
Interplanetarry travel is a lot harder than most people think...
Re:The Problem with Space Travel (Score:3, Funny)
I hate this part! (Score:2)
the technical article (Score:4, Informative)
http://xxx.lanl.gov/abs/astro-ph/0201003
The universe isn't a very friendly place... (Score:2, Interesting)
Ever heard of a little something called binary black holes?
This little thingies has two tightly focused, _really_ hot jetstreams of radiation going out in opposite directions, but doesn't emitt much in other directions (They're black holes after all, so they suck up pretty much everything that could make them detectable).
Well, now imagine a spinning binary black hole.
It'll be almost undetectable... until it happens to spin so that one of the jetstreams hit a planet and fry it to a crisp.
We _could_ have things like this just around the corner (astronomically speaking) and not be aware of it.
I don't know how common this type of celestial bodies are, but for life, they are definitly a Bad Thing, since they could effectivly "reset" a planet and life would have to start all over again...
this is Asimov's universe (Score:2, Informative)
that. You'd just see deserts and a little bit of scum in the water. Worms and such developed in the last 12% of the earth's age. Fishes and plants in the final 6%.
What about the Moon? (Score:4, Interesting)
So, how many of those planets have comparable Moons around them?
Re:What about the Moon? (Score:4, Insightful)
Beyond that, there's an increasing body of evidence that early life was highly extremophilic and more likely formed deep underground or near a deep-sea hydrothermal vent. I don't know of -any- hard evidence that tidal pools played a large role in biogenesis; it's all speculation as far as I know, though I'm admittedly only an astronomer, not an astrobiologist.
Re:What about the Moon? (Score:3, Interesting)
Earth has these little continents that leave the thin tectonic plates (made of denser rock and covered with vast oceans) free to move around. Imagine how different Earth would be if all the rock that currently orbits us were instead filling the ocean basins and keeping the plates from moving around.
A few back-of-the-envelope (containing some stupid coupon from AT&T Broadband) calculations gives about 2x10^19 m^3 for the volume of the Moon, 5 x 10^14 m^2 for the surface area of the Earth, so, spreading the moon out evenly (and neglecting curvature), a layer 4 x 10^4 m thick. Granted, it might not all be silicate, but it's a lot of rock, especially considering that the average depth of the oceans is around 4 x 10^3 m, and the plates under the oceans are around 5 x 10^3 m thick (results of random web searches).
Something to think about the next time you look up at the Moon.
Great offer!!! (Score:3, Funny)
I will give you half of my share of the planets if you can tell me how to get there and back, safely and for a reasonable price.
This is what we should do: (Score:4, Interesting)
Billions of Habitable Planets (Score:3, Interesting)
Recall that a couple of decades ago, Carl Sagan hypothesized that planets that could spawn intelligent life could have equal potential to self destruction to Earth... Chances are, if we manage to visit some of these planets, we'll find some ancient broken down probes, and maybe some nuked out cities, devoid of life...
Ha .. better yet .. (Score:2)
:-P
Re:It would be cool (Score:2, Interesting)
Well, I'm no expert (I'm not even an amateur), but I have heard that an array of optical telescopes (particularly if they could be placed on a solid airless body like the moon) could have the ability to optically resolve planets around other stars.
This would be an expensive undertaking, but it would resolve the issue pretty quickly. I think that positive confirmation of extrasolar Earth-like planets would be an amazing, culture changing phenomena, right up there with actually discovering extraterrestrial life.
PI think my info on optical telescope arrays came from Entering Space [amazon.com] by Zubrin.
Re:It would be cool (Score:2, Interesting)
Fairly interesting, and I hope these guys get their plan adopted.
Thunder
Re:It would be cool (Score:2)
There is one currently in the works that will use an array (4,6?) in orbit to do the same thing.
Discovery Science had a program with Jonathan Frakes narrating the other night on this. They also cover the Jupiter/Protector theory.
Backwards (Score:3, Interesting)
Re:The number of habitable planets... (Score:2)
Survivor. Nope
3's Company reruns. Definitely not.
Snippy British gameshow host making fun of the idiot contestants. OK, that's 1, but we _really_ don't want to meet her...
Re:Probabilities (Score:2)
Bah. The problem with simplistic explanations as to why "abiogenesis is impossible" is that scientists have very good answers such so-called proof of impossibility.
The short story: you can prove anything if you start with a false premise. And unfortunately, the premise underlying your supposed proof of impossibility is false.
Those who are actually interested in the science of biology rather than creationist dogma might be interested in this page [talkorigins.org].