If
you're someone who is remotely interested in space, you won't
have failed to notice the headlines that pop up every few months
about scientist’s latest discovery of a 'potentially habitable
planet' – ‘Hey look, we found a planet only twice as large as the
Earth, possibly orbiting in the habitable zone of its star, that's
only 400 light years away!’
Now
yes, I'm not saying we should ignore the latest Kepler discoveries.
Nobody has ever done this before, and the spotting of more than 2,000
exoplanets since 1988 is indeed a scientific milestone. Personally, I
remain a huge fan of SETI.
But
as someone who (secretly) hopes to earn my stripes as a hard
science-fiction author someday, I can't help but remain a bit
skeptical. Will these far-flung worlds ever really affect the destiny
of the human race?
Might
it not be the case that, in however many centuries it takes us to
reach them, we come up with much better alternatives when it comes to
finding a place to live? Might these worlds become obsolete long
before anyone has a chance to do their Neil Armstrong impression?
Let’s
step back for a moment.
Say
all of 21st century humanity, as we know it, was just a tribe from
the Stone Age living in a cave somewhere. It’s a cave, but it’s a
nice cave, nestled in a hillside, over a river, surrounded by fertile
soil. Not a bad place to live.
Now
imagine one of the young hunters goes off exploring, and returns a
few days later with exciting news.
‘Hey
guys! You'll never believe what I found! There's another cave we
could live in! I mean...its kinda small, its filled with poisonous
moss, oh and its in the middle of the desert...two hundred miles
away, but still!’
And
indeed, maybe some members of the tribe eventually do make the
arduous journey and attempt to live there. Maybe they even find it
tolerable, and this sets a precedent, with other bands setting off to
colonize caves of their own.
In
this manner, Stone Age humans might have crossed entire continents,
seeking out more and more caves in which to live. In time,
Civilization might have arisen from these underground refuges.
Underground wars would have been fought. Cave-based empires would
rise and fall. Shakespeare might have written Hamlet under the
stalactites.
Indeed,
if you had gone back and asked whatever budding science fiction
writers may have existed in 10,000BC, this is how they might have
pictured the future - a world in which humanity spreads across the
Earth, inhabiting every single cave? Whoa!
There's
a little flaw in this story though, an unexpected factor that makes
this just an alternate history. While humans have sometimes lived in
caves, civilization as we know it did not ultimately center on their
existence. At some point, someone invented an alternative form of
habitation, one that proved superior to caves in most respects.
We
call them houses.
The
Rise of the Cosmic House
In
case it’s not clear what I'm on about, the caves in this analogy
are the planets themselves. As for the houses - that's a little
harder to describe. So what is the interstellar equivalent of a
house?
While
the cave analogy is mine, I can't claim credit for this entire idea.
We have already seen it in works from authors like Iain M. Banks and
Stephen Baxter.
In
Banks's 'Culture' universe, most citizens of the advanced,
star-spanning Culture live on enormous, galaxy-crossing spaceships or
giant, artificial habitats. Planets are considered little more than
nature preserves, inhabited by primitive races yet to develop
spaceflight.
I
also recall a Stephen Baxter story where a character becomes the
first man to land on an asteroid. At first, he's little known, with
most of the glory going to the first man on Mars. In time however,
the Martian cities decline, the planet is largely abandoned, and the
bulk of humanity ends up living in space. The protagonist does to the
Martian Neil Armstrong what Christopher Columbus did to Leif Erikson.
In
the end, it is those who leave a lasting legacy that achieve true
glory. Space is where our future lies, not planet-bound like our ape
ancestors.
Many
studies have been conducted in to what future space habitats may look
like. The jumbled mess that is the International Space Station will
be looked back upon as the first roughly hewn raft our ancestors
assembled on a beach somewhere.
Names
like Bernal Sphere, Stanford Torus and O'Neill Cylinder have been
floating around for a while now. These consist of different versions
of what is essentially the same thing - a rotating space habitat.
The
basic idea is that space habitats need to rotate in order to produce
centrifugal force, thereby imitating the gravity of a body like
Earth. These generally take the forms of cylinders, wheels or
spheres. A cylinder a thousand meters across, for instance, would
need to rotate about once a minute to approximate 1G.
There's
no reason to believe such habitats could not be built in the near
future. I'll stress again - this is science, not science fiction.
A
very early example would be ‘Space
Station One’ -
the rotating wheel we see early in 2001:
A Space Odyssey.
The building of much larger habitats is certainly possible. ‘Rama’
from Rendezvous
with Rama (also
by Arthur C. Clarke) is a larger example, being a rotating cylinder
some fifty kilometers long and twenty wide.
I
can even imagine looking up at the night sky in a hundred years or so
and seeing hundreds of cylinders, spheres and wheels the size of
cities orbiting the Earth. Probably the best description of this
we've seen so far would be Alastair Reynold's 'Glitter Band' of ten
thousand space habitats orbiting the planet Yellowstone in
his Revelation
Space novels.
Some
authors have presented us with even larger structures, such as
the Halo Ringworlds
(about 10,000km across), Iain M. Banks' Culture Orbitals (3 million
km across) and Larry Niven's titular Ringworld (300
million km across!)
Of
course, the ultimate extension of this principle is a ‘Dyson
Sphere’
- a
swarm (NOT a solid shell) of enormous solar power collectors
partially or entirely surrounding a central star. Such a structure,
if placed around our own sun, could collect nearly a million, billion
times as much energy as current global electricity consumption.
So
one has to ask - amidst all this, what place is there for planets?
Planets
vs. Space Habitats: A Losing Battle
When
it comes to qualify of life, planets just can't compete.
For
starters, planets are horrendously inefficient users of space. The
whole point of a sphere is to minimize the
surface area of an object after all, making planets literally
the worst
possible option.
The
Earth weighs nearly six trillion, trillion kilograms, but has a
surface area of barely 500 million square kilometers. If you
disassembled the Earth and used its material to manufacture rotating
space habitats, even if the thickness of their shells averaged say, a
kilometer (and it could be a lot less) you would increase the
available surface area over two thousand-fold.
Not
only would you have more space (who needs a mantle or a core after
all?) but your new environment would be infinitely more malleable
than your old one.
For
starters, your new home's gravity can be turned up or down like the
volume control on a stereo. Just spin the habitat a little faster and
it goes up. Do the opposite and eventually you'll be back in free
fall.
This
is one of the biggest issues people tend to have with planets. Mars,
while many argue it is ripe for terraforming, has the downside of
possessing only 38% as much surface gravity as Earth. For us
Earthling this adjustment isn't so bad (it could even be viewed as a
positive) but for our descendants who may grow up there, returning to
the mother planet could be a big issue. Only advanced medical
technology (perhaps a pill that can regrow your atrophied bones)
might surmount this obstacle.
Even
then, a humanity that spreads across the cosmos will surely splinter
into innumerable factions. A big divide between them may be gravity.
Is a full Earth gravity really ideal? Or would it be better to just
live in microgravity? Is there some ideal figure somewhere in
between?
Many
problems with transportation here on Earth relate to either gravity
or air friction, both of which are really quite punishing down here.
On Titan for instance, with gravity a sixth of Earth's but a denser
atmosphere, people could reportedly flap around with wings strapped
to their arms. This will never be possible on Earth.
So
I stress - the first problem with planets is the gravity is not
malleable. You're stuck with either one or 38% or a sixth of a Gee,
or whatever the local constant is.
Other
aspects like temperature, air pressure and humidity can all be
adjusted in space like the air conditioning in your home. In fact,
this brings us to another major flaw that tends to reduce
planet-bound property values.
Planets
are dangerous.
About a hundred thousand people every year die in natural disasters
of some sort. So far in the 2010s, the biggest killers have been
earthquakes, temperature extremes, floods and epidemics.
With
improved technology, these numbers tend to plummet drastically (the
vast majority of these casualties occur in developing countries) but
it’s hard to see them ever disappearing entirely. The 2004 Indian
Ocean earthquake released as much energy as 500 million Hiroshima’s
while the average hurricane releases more energy than the global
annual electricity consumption. It’s hard to see any civilization
dismissing such forces as mere trivial concerns.
While
such risks may seem minor to us, I fear our descendants will be much
more safety conscious, particularly if we end up curing the aging
process and living more or less forever.
I'm
not sure that the average person on 21st century Earth has fully
absorbed the implications of geology either. The knowledge that we
are not in fact standing on solid ground - that thirty or forty
kilometers beneath our feet is a broiling sea of liquid magma the
same temperature as the surface of the sun, one on which the plates
of the Earth's crust slip and slide like rafts...let’s face it,
it’s a terrifying reality we're all just quietly ignoring.
But
earthquakes, volcanoes, hurricanes, tornadoes, lightning storms,
blizzards - all are optional extras on your brand new space habitat.
Another
problem is accessibility. Planetary surfaces lie at the bottom of
deep gravity wells. On Earth, you have to accelerate anything up to
at least 11 kilometers a second just to even reach space. The
building of space elevators may reduce launch costs, but passengers
will still be subject to lengthy rides up and down the tether that
could last for days.
In
space meanwhile, a habitat would generate very little actually
gravity. Spaceships could dock with it much like a ship at a pier.
A
further difference is one of security. Planets, being massive balls
of solid matter, are close to impossible to move. They are destined
to follow the same orbit around their parent star for millions of
years.
To
anyone with a vendetta against your civilization, they make fat,
juicy targets. All you have to do is fling an asteroid out of orbit
or fire a giant space laser at just the
right moment, even from light years away, and your salvo will
eventually impact with the planet in question. Any idiot with a giant
space laser in the Alpha Centauri system could blast the Earth no
problem, and with no warning.
Space
habitats meanwhile, are much more mobile (except perhaps some of the
larger examples mentioned here). As long as you occasionally fire
your thrusters to shift your station's orbit, even slightly, this
will foil that dastardly plot by the inhabitants of the Alpha
Centauri system. It’s like the difference between trying to hit a
ship or a city with an ICBM. This is not a foolproof defense of
course, but it does make things light years easier.
One
final advantage I'll mention is the availability of resources.
Potentially habitable planets are not expected to be found in more
than maybe 1 in 10 star systems. If we were to remain a planet-bound
civilization, the other 90% would go unused.
With
space habitats however, you can construct them pretty much anywhere.
There’s no reason to believe that asteroids in some quantity won’t
be found around virtually all stars. Our own solar system contains at
least a million larger than 1km in diameter. Wherever we go, such raw
materials should be abundant. The same off course applies to the
solar energy you need to power your mining operations.
So
as you can see, your brand new Space Habitat 5000 has numerous
selling points - greater living space, adjustable gravity, climate
control, geological stability, accessibility, security and
availability of resources to name a few.
Honestly
- what poor fool would still choose to anchor themselves down on a
planet?
So
What Good Are Planets?
All
this isn't to say of course, that our descendants will utterly ignore
planets. I'll admit the title of the article exaggerates slightly.
The
first exception I'll concede is that we probably will have a crack at
colonizing Mars in the near future. We may even succeed if Elon Musk
has his way.
There
are an enormous number of technological, political, economic and
social challenges to overcome however. Are we really going to
redirect some asteroids to slam into the Martian poles in order to
melt them for instance? Or will the whole thing be interrupted by a
band of Greenpeace protesters who've chained themselves to the top of
Olympus Mons?
Once
we move beyond the Solar System however, what exactly is the appeal
of planets?
Admittedly,
planets may have a few redeeming
features. Any space habitat will be more vulnerable to sudden
decompression in the event of a hull breech for instance, but this is
probably a manageable risk. After all, houses have walls much less
thicker than caves, but we make do. Space habitats will also require
more regular maintenance than a planetary environment, especially
with regards to issues like the disposal of waste.
And
I suppose that even today, caving is still a sport, and there's
plenty of interesting creatures to be found beneath the Earth. No
doubt they'll always be some mad scientist willing to plant the flag
on whatever bizarre, inhospitable rocks we come across in due course.
Some offshoot factions of humanity, perhaps homesick for the feel of
real rock beneath their feet or the look of a sunset, may go like
Gollum and decide to live in these cosmic caves anyway.
So
yes, I'll grant a substantial minority of humanity may still call
planets home.
What
I'm saying is - just as human civilization has not been focused on
caves for something like 10,000 years (if it ever was) interstellar
civilizations are unlikely to center around planets. Most people will
likely live in space.
I
would also like to point out, just in case anyone got the wrong idea,
that I am not personally in favor of the idea of dismantling the
Earth and turning it into millions of space habitats. The Earth, as
our home, will always have a special place in galactic history. I
personally would be in favor of keeping it as a nature preserve. Its
native wildlife - from beetles to lions to Amish, should be able to
roam its surface into perpetuity. The rest of humanity, cruising the
galaxy in our vast space arks with our minds uploaded into computers,
or come what may, should leave them in peace.
Any
planets that we discover with their own native life should also be
preserved. Aside from covert scientific expeditions, they will
probably be basically forbidden for anyone else to visit. As for
tourism, I don't see why it can't be conducted virtually. That's
probably where our future lies anyway.
But
as for the rest of the universe - go nuts. I'd start with Mercury,
Its three hundred million, trillion kilograms of barren, iron-rich
rock, ripe for harvesting. Can you imagine the solar arrays we could
unfurl with such a goldmine?
I
am here merely to point out yet another big lie most science fiction
clings to. Sci-fi universes like Star Trek and Star Wars are always
filled with warring factions competing over precious, precious
planets.
Why?
Why
are they doing that?
Why
not just harvest a few asteroid belts, construct a few thousand
artificial habitats capable of housing your billions of excess
citizens, and call it a day? The total carrying capacity of the
Solar System, were we to convert even a fraction of its usable
material into biomass, is easily trillions of times that of the
current human population.
As
has been pointed out before, a plotline that sees aliens invading
Earth to steal our water is like Eskimos invading Central America to
steal their ice.
Any
interstellar empire focused around planets makes about as much sense.
