Ok. First of all
Rhadamantus the multiple consecutive posts need to go. You can incorporate multiple replies by doing the following:
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[quote="other user name"] TEXT[/quote] (make sure you use the quotation marks)
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repeat ad infinitum
That having been said, I am going to explain some things to you.
Rhadamantus wrote:Fuck.
Right. This means that habitable planets are around 10% of star systems. If that's true, then there should be tens of billions of habitable planets in the galaxy. Since life seems commons, there should be billions of civilizations that have existed, and hundreds of thousands around now. There aren't. Therefore, either we can't find them, life is difficult, or intelligent life exterminates itself easily.
There are a lot of reasons why this is not necessarily true.
For starters being tidally locked does not necessarily mean that the planet does not have a magnetic field or is not rotating. Tidal locking means that the speed of orbit matches the speed of rotation. This does not preclude a magnetic field around the planet as long as the core of the planet remains molten.
Now, some radiation will get through anyway with a flare star, but that is OK. A molten core means tectonic activity and tectonic activity means that life probably started like it did on our little ball of dirt. Around deep ocean vents. As long as that is true, life can evolve resistance to radiation. We have living things alive on this planet right now that can happily withstand--completely unprotected mind you--the radiation doses of 500k-1.5 million rads through a combination of polyploidy and rapid DNA repair mechanisms. So long as the early stages of life evolve in a protected environment like deep ocean vents, natural selection will take care of the rest.
A civilization even a century more advanced than us would probably have fusion drives. Those would be detectable from a distance of a 100 ly. We've seen nothing.
Why would they?
Here, let me show you some math.
Rd = ( 17.8E6 * sqrt( Ms*As*Isp*(1-Nd)*(1-Ns) ) )
where:
Rd = maximum detection range (kilometers)
Ms = bogey spacecraft mass (tons)
As = bogey spacecraft acceleration (G)
Isp = bogey drive specific impulse (seconds)
Nd = bogey drive efficiency (0.0 to 1.0)
Ns = bogey "stealth efficiency", i.e. fraction of waste energy which can be magically shielded from enemy detectors. (0.0 to 1.0)
So lets take the
Space Battleship Yamato weighing in at ~70000 tons, it uses a Magneto Inertial Fusion drive that can accelerate it to 20 Gs for some horrifying reason. Specific impulse is 5140 seconds, we will call Nd .5 and NS 0.0
( 17.8E6 * sqrt( 70000*20*5140*(.5)*(1) ) )
This puts the detection distance at 1.06E12 km, Proxima Centauri is at 4.13E13, so that honking big fusion drive would not be detectable at earth from Proxima Centauri.
I dont know what the parameters are on the fusion drive cooked up by Zubrin, but...
If a civilization has moved on from building fusion drives, then they have either fallen back or used something more advanced. More advanced stuff would be more easily detectable.
That is not necessarily true. An anti-matter torch drive for instance (dear god) would be governed by the same equations. We might detect it as stray photons from a gamma ray burst, or because of the inverse squared law, we might not detect it at all. Unless they were detonating multi-terraton antimatter bombs as part an antimatter orion drive, we are unlikely to detect that. Our telescopes and detectors just dont have the resolution to distinguish that from the background noise.
Ok, the fusion rockets is not the best argument. Though I would argue that we should point telescopes at stars to try to see if there are fusion drives going off there.
Why would we see them? If we point telescopes at star systems, any fusion drive will get lost in the glare of said star unless it somehow manages to outshine the star itself by a significant margin.
