LIFE on Earth was all neatly packed up inside a pucklike container and ready to blast off on an unmanned Russian mission to a Martian moon this month.

Stranger

After more than 10 months traveling through deep space, the Planetary Society's Living Interplanetary Flight Experiment would land on the surface of the Martian moon Phobos with its cargo of voyagers from all three kingdoms of life, including tiny, extremely hardy animals called tardigrades.

Then, after a couple of weeks on the surface, the first Earthly life to have lived on another solar body would return to Earth. A tiny, robotic, interplanetary lander was going to spring off the base craft, fire off its rocket, and hurtle through space before crash landing in Kazakhstan.

Now, though, Russian space officials have delayed the mission due to safety and technical problems that typically plague ambitious trips beyond low-Earth orbit. And because of the nature of Earth's orbit in relation to Mars, the Planetary Society-backed researchers will have to wait two long years before their next launch window to determine if life could have originated outside Earth and hitched a ride here.

Despite the delay, LIFE will eventually get a chance to fly, assuming the funding will remain in place.

"LIFE is a test of part of the so-called transpermian theory to see whether life can travel through space between planets," said Bruce Betts, the experiment's manager at the Planetary Society, which was co-founded by Carl Sagan. "If we send a bunch of microorganisms out to space for three years, will they still be alive?"

We already know that plenty of life forms can survive in low-Earth orbit. In fact, we've sent up all kinds of living things, including dozens of animals and various kinds of nasty bacteria.

But deep space is different. At the International Space Station, say, the Earth's magnetosphere protects life from radiation. We're not really sure what will happen when life is exposed to the depths of space for years. The Biostack 1 and 2 experiments, flown during the Apollo 16 and 17 missions to the moon proved organisms could survive during a two-week journey through space. But that's not long enough to simulate the hypothetical journey of bacteria from Mars to Earth.

"It's a see-what-happens experiment, which you don't get a lot of anymore," Betts said.

If the living things in the LIFE experiment survive the 34-month journey aboard the spacecraft Phobos Grunt, it would provide support for the idea that living things could travel between planets aboard rocks ejected by cosmic collisions.

On the other hand, Betts said, "If you find everything is dead and confirm it's not some fluky other thing, then it casts more doubt on whether life can travel between the planets."

They fought through months of bureaucracy, both in the United States and Russia, to make the mission happen.

"Because this launch is on a spacecraft, we are subject to [International Traffic in Arms Regulations], so the Planetary Society is registered as what you might call an arms tracker," Betts said.

If the governments were a hassle, the engineering assignment was much worse. Completing the packaging of 30 living specimens into a tiny 100-gram "BioModule" consumed the team as they raced to send off their part of the mission to Russia.

"You need to understand the constraints for the Phobos mission," Betts said. "We had 100 grams. We had to be passive. We had to not interfere with anything else. And, by the way, you have to survive a 4,000-g impact."

The Phobos lander won't have a parachute, so it's possible the landing will bring intense forces to bear on the scientific instruments. It's imperative, too, that the organisms remain sealed in their container for the duration of the journey, so they won't contaminate Phobos.

To test the BioModule's durability, they first filled the inside with fluorescent liquid, so that any leakage would be apparent. Then, the scientists strapped it to a shake table and violently vibrated it. Then, they shot it out of an air cannon onto a target. The first iteration of the BioModule leaked a bit of its fluorescent liquid, but held tough in the second round.

Sitting tight now, though, has become the scientists' main task.

More photos of the assembly and testing of the LIFE experiment can be found on the following page.

Images: 1) The LIFE BioModule. 2) The BioModule strapped to the shake table.

Bruce Betts

Here we see the LIFE samples loaded into specialized vials. Most of the organisms were freeze-dried in preparation for flight.

A completed vial array, containing 12 samples of the same organism. Three samples of each organism were put into the BioModules. There were also backups and controls.

From the vial trays, the samples were loaded into the circular BioModule itself.

Here, we see the components of the completed module, including the titanium casing and the samples.

Everything gets fit together and sealed.

This is the projectile that the BioModule was strapped to for air-cannon testing.

The team at the target after successful testing.

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