intouea.com

Could a Saturn moon harbour life?

Gap fill

Watch the video, complete the gaps on a piece of paper, then check your answers.

Two years ago here at TED I reported that we had discovered at Saturn, with the Cassini Spacecraft, an anomalously
warm
and geologically active region at the southern
tip
of the small Saturnian moon Enceladus, seen here. This region seen here for the first time in the Cassini image taken in 2005. This is the south polar region, with the famous tiger-
stripe
fractures crossing the south pole. And seen just recently in late 2008, here is that region again, now
half
in darkness because the southern hemisphere is experiencing the onset of August and eventually winter.
And I also reported that we’d made this
mind
-blowing discovery -- this once-in-a-lifetime discovery of towering jets erupting from those fractures at the south pole, consisting of tiny water
ice
crystals accompanied by water vapour and simple organic compounds like carbon dioxide and methane. And at that time two years ago I mentioned that we were speculating that these jets might in fact be geysers, and erupting from
pockets
or chambers of liquid water underneath the surface, but we weren’t really sure. However, the implications of those results -- of a possible environment within this moon that could support prebiotic chemistry, and perhaps life itself -- were so exciting that, in the intervening two years, we have focused more on Enceladus.
We’ve
flown
the Cassini Spacecraft by this moon now several times, flying closer and deeper into these jets, into the denser regions of these jets, so that now we have come away with some very
precise
compositional measurements. And we have found that the organic compounds coming from this moon are in fact more complex than we previously reported. While they’re not amino acids, we’re now finding things like propane and benzene, hydrogen cyanide, and formaldehyde. And the tiny water crystals here now look for all the world like they are frozen droplets of
salty
water, which is a discovery that suggests that not only do the jets come from pockets of liquid water, but that that liquid water is in contact with
rock
. And that is a circumstance that could supply the chemical energy and the chemical compounds needed to sustain life.
So we are very encouraged by these results. And we are much more confident now than we were two years ago that we might indeed have on this moon, under the south pole, an environment or a
zone
that is hospitable to living organisms. Whether or not there are living organisms there, of course, is an entirely different matter. And that will have to await the arrival, back at Enceladus, of the spacecrafts, hopefully some time in the near future, specifically
equipped
to address that particular question. But in the meantime I invite you to imagine the day when we might journey to the Saturnian system, and visit the Enceladus interplanetary geyser
park
, just because we can.

Transcript

Two years ago here at TED I reported that we had discovered at Saturn, with the Cassini Spacecraft, an anomalously warm and geologically active region at the southern tip of the small Saturnian moon Enceladus, seen here. This region seen here for the first time in the Cassini image taken in 2005. This is the south polar region, with the famous tiger-stripe fractures crossing the south pole. And seen just recently in late 2008, here is that region again, now half in darkness because the southern hemisphere is experiencing the onset of August and eventually winter.

And I also reported that we’d made this mind-blowing discovery -- this once-in-a-lifetime discovery of towering jets erupting from those fractures at the south pole, consisting of tiny water ice crystals accompanied by water vapour and simple organic compounds like carbon dioxide and methane. And at that time two years ago I mentioned that we were speculating that these jets might in fact be geysers, and erupting from pockets or chambers of liquid water underneath the surface, but we weren’t really sure. However, the implications of those results -- of a possible environment within this moon that could support prebiotic chemistry, and perhaps life itself -- were so exciting that, in the intervening two years, we have focused more on Enceladus.

We’ve flown the Cassini Spacecraft by this moon now several times, flying closer and deeper into these jets, into the denser regions of these jets, so that now we have come away with some very precise compositional measurements. And we have found that the organic compounds coming from this moon are in fact more complex than we previously reported. While they’re not amino acids, we’re now finding things like propane and benzene, hydrogen cyanide, and formaldehyde. And the tiny water crystals here now look for all the world like they are frozen droplets of salty water, which is a discovery that suggests that not only do the jets come from pockets of liquid water, but that that liquid water is in contact with rock. And that is a circumstance that could supply the chemical energy and the chemical compounds needed to sustain life.

So we are very encouraged by these results. And we are much more confident now than we were two years ago that we might indeed have on this moon, under the south pole, an environment or a zone that is hospitable to living organisms. Whether or not there are living organisms there, of course, is an entirely different matter. And that will have to await the arrival, back at Enceladus, of the spacecrafts, hopefully some time in the near future, specifically equipped to address that particular question. But in the meantime I invite you to imagine the day when we might journey to the Saturnian system, and visit the Enceladus interplanetary geyser park, just because we can.

Thank you.