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tempered engineer an ulcer, Galileo made it to Jupiter in late 1995 and, seemingly against all odds, it worked. Unlike the Voyagers, which were
flyby missions, Galileo is an orbiter. When it got to Jupiter, it fired its powerful rocket perfectly, slowed down, and established permanent
residency, becoming (as far as we know) the first artificial moon of
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Jupiter. For eight years it circled Jupiter, caroming among the Jovian
moons, scanning and photographing each of them on repeated close
passes.
Now Galileo, its mission completed, is crippled but triumphant, near
senile from radiation damage and hobbling through its final orbits with
that pathetically crumpled main antenna still in tow, its failing gyros
barely able to keep the ship oriented. As of this writing, Galileo is
scheduled to be intentionally crashed into Jupiter in September 2003.
Why don’t we just leave it in orbit? Because it might someday smash
into Europa, contaminating that world with flecks of plutonium and,
conceivably, some stowaway bacteria. It seems unlikely, but who can
say? Diving Galileo into Jupiter while we are still able to control it is the responsible thing to do.*
A S U R P R I S E I N S I D E
Galileo carried the first digital camera ever flown in space and, while
bouncing among Jupiter’s moons, made photographs with a level of
sharpness and detail new to space exploration. The strange beauty of
these distant worlds raises some questions: Why should these places,
where no terrestrial eye can ever before have wandered, be beautiful to
us? What structures, deep within our brains or deep within the physical
universe that created both Gaia and Europa, are resonating when we
gaze upon an alien landscape for the first time and find exhilarating
beauty? Would alien souls feel it, too?
What we have found here is something much more profound than
simply a random collection of odd worlds. These large, complex moons
are really planets in their own right, and Galileo is humanity’s first
exploration of a new planetary system. As you might expect, many
comfortable preconceptions have been completely overturned. Much of
what we thought we knew about comparative planetology turns out to
be wrong. This includes our previous notions of where interesting geo-
logical—and biological—activity may be found in the universe. The
moons of Jupiter, as glimpsed by the Voyagers and explored by Galileo,
turn out to be a much more active and diverse gang of worlds than our
previous theories of planetary evolution would have led us to believe.
*Wouldn’t it be ironic if in our effort to protect the Europans we ended up nailing some poor Jupiterian gas creature?
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We thought that only large, rocky worlds like Earth could have
active geology, and that we would find only dead ice worlds out this far
from the Sun. But who needs a star when you’ve got a giant planet like
Jupiter? Several of those moons are seething with internal heat, rest-
lessly churning inside and out. It is Jupiter’s influence that creates this
heat and activity. Just as our Moon tows the oceans around the Earth,
the huge gravitational pull of Jupiter yanks the insides of these moons
around, creating the internal heat that drives the furious volcanic activ-
ity of Io and continually warms and cracks the ice on Europa.
This surprising activity is facilitated by the tight, polyrhythmic
orbital dance continually executed by the three innermost giant moons.
Io orbits Jupiter twice for one Europa orbit, and similarly Europa laps
Ganymede twice each orbit. They are locked together tighter than the
tightest rhythm section in Jamaica. Every time they pass, they grab at
each other with gravitational arms, but Jupiter pulls them back into
line. This rhythmic back-and-forth keeps them flexing, pumping energy
into their interiors. The heat of the dance keeps their insides hot and
their faces young and fresh. The greatest heating goes to those caught
most deeply in Jupiter’s gravitational spell. Thus we see an evolution of
planetary style, each moon getting progressively colder, and its surface
older, as we travel outward from innermost Io past Europa, Ganymede,
and Callisto. The only moon that receives no internal heating from this
intricate multipartner dance is outermost Callisto. Like an older chap-
eron watching the young ones dance and bloom, Callisto comes closest
to our original expectations of all the Jovian moons—an ancient, dead,
heavily cratered ice world.
The active nature of these moons was actually predicted right before
the Voyager discoveries. In a triumph of theory, and an example of
good timing, three planetary scientists* modeled the effect of tidal heat-
ing on Jupiter’s moons and predicted that Io would be volcanically
active. Their paper was published in Science one week before Voyager 1
arrived at Jupiter. When Voyager 1 flew past Io, dang if they weren’t
right there: giant volcanic plumes shooting off into space from the
edges of the little red moon. The plumes astonished everyone (including
the scientists who had made the prediction).
Europa, too, gets a workout on the inside from those Jovian tides,
but we don’t know exactly how much heating it gets. Some models pre-
*Stan Peale, Pat Cassen, and Ray Reynolds.
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dict that the icy surface is just a thin shell, a few kilometers thick, over
a deep liquid ocean. Others suggest that the icy shell is tens of kilome-
ters thick, but increasingly, nearly everyone accepts the likelihood of a
deep ocean beneath the ice.
Ever since Voyager we’ve wondered just how active Europa might be
and what really goes on there, and science fiction writers have riffed on
the theme of Europan life. Now, seen through Galileo’s digital eyes, it
turns out to be arguably the weirdest world we’ve yet explored. On
first viewing, its planetwide system of dark fissures and raised bands
looks like a global tangle of roots. The face of Europa seems eerily
unnatural, with animated landscapes suggesting arrested flow. At every
scale, from hemispheric to close-up, the globe is covered with what
could almost be veins, like a giant, frozen mutant leaf.
Europa looks alive. Its bright, lineated surface is composed of fresh-
water ice crisscrossed by a global system of fissures and cracks, formed
as the surface pulsates with the tide. Galileo has now shown us the sur-
face at a magnification a thousand times Voyager’s best. In the most
detailed photos we see icebergs, which have apparently broken loose,
floated, and jostled before freezing in place again. This adds to a
mounting pile of evidence for an ocean of liquid water beneath the ice.
In fact, we now think that Europa may have more water than all of
Earth’s oceans combined. And, on Earth at least, where there is water,
there is life. Does anything swim through Europa’s icy seas?
As far as I know, the possibility of life in underground oceans on icy
moons was first mentioned in 1975 by Guy Consolmagno, another
John Lewis graduate student, in his master’s dissertation at MIT. Guy
(who is now a Jesuit priest as well as an active planetary scientist) was
studying the thermal evolution of ice moons. His calculations showed
that they should sometimes develop layers of liquid water within. The
appendix of his thesis ended, “But I stop short of postulating life in
these oceans, leaving that to others more experienced in such specula-
tions.”* This passing comment in a student dissertation went mostly
unnoticed, but the possibility of life on Europa became a hot topic after
Voyager’s discoveries. Arthur C. Clarke made it one of the main themes
of his novel 2010, published in 1982 when the new images from
Voyager were fresh on our minds.
*Reflecting on this now, Guy wrote to me, “So I guess that makes me the first person NOT to predict life in these oceans!”
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Image unavailable for
electronic edition
With Galileo’s further hints of a deep, dark ocean, Europa has
emerged as the most promising place to look for water-based extra-
terrestrial life in our solar system. Indeed, this bizarre little moon can
serve as a test bed for our current assumptions about life.
We are currently planning a mission that we hope to launch some-
time in the next decade to orbit Europa. It will determine definitively
whether an ocean is flowing within. We’ll also look more closely at the
surface for life-revealing chemicals mixed into the ice. If we do confirm
the presence of liquid water, the next step will be to go ice fishing. We’ll
go back and land a self-disinfecting probe that can slowly melt through
the icy crust. Then, when we break through to open water, we’ll go
exploring in our solar system’s deepest ocean.
G R A V I T Y ’ S R E I G N
We thought the Jovian system would be a fossil, a freeze-dried remnant
of the early solar system. Instead close-up spacecraft investigations
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revealed a living, evolving planetary system. The unanticipated activity
and youthfulness of these worlds implies that gravitational energy may
be of equal or even greater importance than solar energy in fueling life
in our universe.
The likelihood of oceans on ice-moons like Europa suggests a whole
new concept of habitable zones. If there can be water, and perhaps life,
on Europa, then the same could be true on moons orbiting giant plan-
ets anywhere in the universe. This would mean that distance from a
star matters less in defining habitability. Such “gravitational habitable
zones” could be common and large, implying a universe with a lot
more real estate having favorable conditions for life as we know it.
The idea of life on Europa has got us all thinking about life that
could be independent of starlight. Meanwhile we’ve discovered
extremophile organisms on Earth that live deep below the surface and
have little interest in the Sun. This may brighten the corners for life and
planetary habitability.
We animals are completely enmeshed in the part of the Earth’s bio-
sphere that lives off the Sun. We’re just a minor outgrowth of the green
world and the ubiquitous, hidden microbial world—we’re those weird
brainy things that crawled out of the compost heap after the oxygen
waste piled up. Its hard for us to imagine life that is truly isolated from
the solar influences that drive and so thoroughly shape our world.
The idea of life underground is not new, of course. Subterranean
creatures have filled our mythologies and occasionally our scientific
fantasies as persistently as have creatures living beyond the sky. Hell, in
the seventeenth century Fontenelle speculated about microbes living
underground on the Moon or elsewhere, slowly eating rocks. Yet now
we have new reason to wonder if perhaps his conjecture was prescient,
and surface life is not the only game in town.
Life may be something that frequently, or even ubiquitously, happens
inside planets. Perhaps biology can be a purely internal planetary phe-
nomenon. If life begins underground, it makes the origin of life any-
where else in the universe less dependent on surface conditions. If all
you need is some internal energy and some liquid water, then most
planets must have the right combo at some point in their history, since
planets are born hot and wet. The classical concept of the habitable
zone starts to seem like a bourgeois notion invented by self-centered,
Sun-worshiping surface dwellers. Can a planetary biosphere that loses
its surface water retreat inward and persist, subterranean and home-
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sick, but still alive? In some cases an “inhospitable” surface may be
only the thick, protective skin covering a thriving underground world.
Astrobiologists agree that there are three essential ingredients for hab-
itability: (1) organic molecules (the building blocks), (2) liquid water
(the medium), and (3) a source of energy (the spark of life). Based on our
studies of comparative planetology, how rare might such a combination
be? Organic matter seems to be ubiquitous, falling from the sky every-
where in the universe, so this requirement serves only to rule out places
with environmental factors that directly destroy organics. No, on sec-
ond thought, it doesn’t even do that. Otherwise, Earth, with its organic-
burning oxygen atmosphere, would be lifeless. Opportunistic life might
find a way to derive energy from whatever it is that destroys organics, as
we do on Earth with high-octane poison oxygen.
The belief that water is necessary and sufficient rests on the assumption that suitable energy sources will be common. How reasonable is this?
Well, the presence of liquid water actually implies some kind of energy
source, so the two requirements aren’t completely separate. Our two
examples of oceanic planets are Earth and Europa. Earth is wet because it
is in the right place to soak up plenty of solar energy. Europa is wet
because of the release of tidal energy. So, both ways that we know of for
a planet to stay watery also come with built-in, long-term energy supplies.
But is tidal energy sufficient to drive a biosphere, or does life need a
sun? Picture the recently discovered dense colonies of bottom-dwelling
life clustered around the “black smoker” volcanic vents on Earth’s
ocean floors. The seafloor on Europa may also have volcanic vents,
driven by internal tidal heat, which could provide the chemical fuel for
a native biosphere.*
Another idea was proposed by Chris Chyba, a former student of Carl
Sagan’s, now at the SETI Institute in Mountain View, California.
Chyba’s idea makes use of the punishing radiation at Europa’s surface.
The powerful magnetosphere of Jupiter whips charged particles into a
frenzy; all of the inner moons exist within a raging storm of radiation.
At Europa, an astronaut in a space suit would receive a lethal radiation
do
se every twelve minutes.† Could a Europan biosphere somehow har-
*Indeed, Europa on the inside may be like a less hyperactive version of fiery, volcanic Io, doused with an outer shell of ice and water.
†Which is one reason why crashing a small amount of plutonium onto the surface may not really be as bad as it sounds.
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vest this potent energy source? Radiation breaks chemical bonds, which
is why it is often lethal. It must be inducing chemical changes in the
Europan crust. Chyba proposed that the radiation rips apart water ice
molecules, liberating hydrogen to drift off into space, and leaving
behind oxygen and various oxidized compounds. Perhaps this oxygen
is eventually mixed down into the ocean where indigenous creatures,
their fragile bodies protected from the radiation by miles of ice,
breathe, harvesting the chemical fruit of the irradiated surface.
The intense radiation at the surface of Europa can be regarded as a
threat to life or as a source of energy that could drive a biosphere.
There is an important concept here that we can generalize to help us
think about life in the universe beyond the biases of our terrestrial per-
spective. Paradoxically, a deadly environmental factor may create
opportunity, if you can control the slide toward destruction. We live by
burning ourselves in oxygen, but slowly, slowly. It’s a fine line between
a deadly chemical or radiation and a bountiful source of energy. Life
may adapt by staying at a safe distance, reaping the flow without being
destroyed by it. Just as our biosphere runs on nuclear energy, keeping
its distance from the solar reactor, underwater life on Europa might use
the intense radiation at the icy surface while avoiding its direct effects.
A whole category of potential adaptations might make use of such
“dangerous,” “lethal” energy sources. Life would need to take advan-
tage of the inevitable flows induced by any source of energy, while
avoiding the destruction that comes from getting too close to the fire.
One thing we know about life is that it is inventive. What seems like a
death ray to us may be a meal ticket for suitably adapted creatures.
B I O S P H E R E T W O
That first voyage by robotic submarine through Europa’s briny sea,
sometime in the next couple of decades, with all the folks back home