Sentient Living Planets Exist
By Adam
Hadhazy
In this weekly series, Life's Little Mysteries rates the
plausibility of popular science fiction concepts.
Warning: Some
spoilers ahead!
Narrators
of nature shows often speak of Earth as a "living planet." To an
extent, the metaphor is true: Biological beings do indeed swim, crawl and fly
through our world's uppermost layers of ocean, land and sky. Plant life covers
much of the Earth, and bacteria and viruses suffuse its soils, waters and even
atmosphere.
But all that is still a far cry from the literally living,
conscious planets that make appearances in many sci-fi and fantasy stories.
Take Mogo in the "Green
Lantern" DC Comics series, for instance.
This planetary entity can change its climate and grow foliage in desired
patterns on its surface at will.
Or
consider Pandora from the 2009 film "Avatar." The flora and fauna on
this lush moon have evolved tentaclelike organs that enable them to neurally
interlink with each other. A globe-spanning consciousness exists, with
Pandora's trillion interconnected trees acting like cells in a colossal brain,
dwarfing our mind's 100 billion neurons.
Could
anything like these far-out scenarios come to be? Creative writers certainly
think so – just check out the long list on Wikipedia of "fictional living
planets."
Yet the
development of a planet-scale being looks to be an extreme long shot. Based on
the chemistries and behaviors of life and nonlife, don't bet on Mogo or
Pandora, scientists say.
"The way evolution works, I can't see it
happening," said Peter Ward, a professor of paleontology at the
University of
Washington.
Megafauna
Planets
come together bit by bit from the gas and dust that surround newly forming
stars. Based on what we have learned from looking at our solar system and
beyond, huge agglomerations of rocks, liquids and gases held together by
gravity will not spring forth into self-aware consciousness.
In one planetary case we know of — Earth — complex
surface chemistry did eventually led to
self-replicating, information-carrying molecules that we deem "life."
That microscopic life over the course of 4 billion years of
evolution has grown to gigantic proportions, such as the blue whale and sequoia
trees. The biggest single organism ever known is
a giant mass of Armillaria
ostoyae fungus sprawling across three
square miles under a forest in Oregon.
Still,
these biological feats are pipsqueaks compared to even a small moon.
"We
have to use Earth's history as a guide," said Ward, wherein the idea of
planet-canvassing organisms, let alone sentient ones, "falls apart to
scientific testing."
Brain drain
A key
reason is physiology. Though vast, that Oregonian fungus lacks neural tissue,
which is the wellspring of the perceptual processing of information.
"Intelligence comes from nerve cells," Ward pointed out.
Creatures
lacking even simple nervous systems, such as amoebas, can still display a wide
range of stimulus-response behaviors. But it takes big brains and highly
developed nervous systems to begin exhibiting intelligence.
Those smarts come at a price, as nerve cells require
enormous amounts of energy. Our brain makes up just 3 percent of our body, yet
consumes 20 percent of our energy. Given this cost, life forms become only as
crafty as evolutionary pressures require. "Very few creatures evolve any
more intelligence than they need," said Ward. [What
If the First Animals to Crawl Out of the Ocean Had Six Legs Instead of Four?]
In
primates, complex social alliances are thought to have fueled human memory and
language skills. Modern carnivores such as dogs and cats do demonstrate high
degrees of social intelligence as well, but only as much as needed. "Dogs
don't need to be any more intelligent," said Ward.
Supposing
a fungus or a web of bacteria grew to cover a landmass – the latter of which
did in Isaac Asimov's novel "Nemesis" – there is not much of a motive
for it to develop sentience, Ward said.
Tooth and nail
Competition
between species also makes a sentient planet seem like quite a stretch.
Picture
any ecosystem on Earth, such as a pond, a forest, a desert. In these
environments, critters (and plants) compete for limited resources of food,
water and territory in order to survive and make more of themselves.
"If
you think about what life is, it has three directives," explained Ward.
"It has got to metabolize in order to get energy, it has to reproduce and
it has to evolve, otherwise it's a crystal and it's not life."
Not only
do species compete against others, but the individuals within a species usually
try to outmuscle their peers. Consider the fights between fiddler crabs for
real estate on the beach, or rival wolf packs over prey.
All in
all, creatures are not programmed to begin cooperating together like the cells
in an individual's body. "With natural selection, someone lives and
someone dies," said Ward. "How do you go from many organisms
competing to one great thing which doesn't compete?"
Collective consciousness
There
are a few exceptions to that rule, however. Insect colonies, for one, are
composed of many thousands of individuals, and these "superorganisms"
act together altruistically to ensure a queen reproduces. "If you look at
bees or ants, those societies are probably as altruistic as one is going to
get," said Ward.
Although
individual ants are not particularly bright, the colony as a whole comes
together to achieve amazing results. An emergent intelligence called a
"hive mind" leads to nest construction, foraging, young rearing,
attack coordination and even agriculture in ant colonies.
So it's
not totally out of the question that a single enormous ant colony could conquer
a world and act as a single mind for the colony's (and the planet's) interests,
until resources ran dry.
Keeping in contact
That
notion, however, brings up yet another issue that would confront a global
consciousness — internal communication.
Ants use
chemicals called pheromones to exchange information; our bodies use nerves.
These methods transmit information quickly across short distances, but getting
a message around a colossal being would take quite a long time.
Even if
a planet-size entity were a robot, like Unicron in "Transformers,"
the regions in its body could not digitally communicate faster than the speed
of light. At planetary scales, "in a giant, connected web" – such as
a mega-computer – "if the thinking is really sort of distributed, it's
going to be slower than anything you have in your house," said Seth
Shostak, senior astronomer at the SETI Institute in Mountain View, Calif.
Room for Gaia?
All
those considerations aside, some scientists have advanced the argument that the
Earth itself should be thought of as a giant organism.
Conceived
in the 1970s, the "Gaia Hypothesis" proposes that life on Earth works
in concert to preserve a mutually sustainable habitat. For example, the
salinity and pH of the oceans are ideal for life because life has made it that
way.
The Gaia
Hypothesis is very controversial, and Ward has disputed it with the fact of
several massive extinction events occurring throughout Earth's history. At any
rate, self-regulating feedback loops still fall short of planetary sentience in
the sense of Earth's biota taking deliberate actions with a group benefit in
mind. "You never get that far," said Ward. "Life screws itself
long before you can get to networked intelligence."
Shostak
is dubious on the matter as well. "After billions of years here, we don't
see a lot of this approach by flora and fauna," he told Life's Little
Mysteries. "They're all interdependent, but they haven’t tried to make a
one world organism kind of thing."
Ultimately,
our definition of life might be too limited to encompass something like Gaia.
But for now, Gaia joins Mogo in the fiction department.
Plausibility score: Virtually no
conceivable mechanism, nor motive, would allow for the development of
planet-size intelligent, biological beings. Unicron and Pandora are great for
the movies, but when it comes to real life, they earn just one out of a
possible four Rocketboys.
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