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U-M simulations correctly predicted that the pulsed jets of the Mars Phoenix lander would strip the soil to the subsurface ice or rock as the craft touched down.
Photos of the area beneath the craft revealed a hard surface that scientists say may be ice. It could also be rock, and researchers won’t know until the Phoenix can dig into the dirt. But it’s evident the craft cleared away soil as it landed.
“This is exactly what was predicted by our group,” says Nilton Renno, an associate professor in the Department of Atmospheric, Oceanic and Space Sciences. “We’ve seen the most amazing photos of the hard surface under the thrusters. The brightness and smoothness suggests it is ice.”
This would mark the first time a spacecraft has touched ice on another planet, Renno says.
Renno and Manish Mehta, a doctoral student in the same department, performed a series of tests for NASA over the past year in part to determine how the lander would affect the place it touches down. Phoenix’s pulsed jet steering and braking system is unique.
Mehta performed the most recent simulations in April at NASA Ames Research Center using properly sized crushed walnut shells and other fine dust particles to simulate the Martian soil. Mehta showed that the pulsed jets could cause a different, more explosive erosion than the continuous jets of the Viking spacecraft, which landed on Mars in 1976. The Phoenix landing process involved thrusters firing in bursts to slow the craft and guide it.
“In our simulations, the pulsed jets excavated to the hard, icy surface within less than a second. The pulses fluidized the bed under the thrusters, so that the soil behaves like water,” Mehta says.
These results were presented May 19 at the Phoenix Science Team Meeting at Tucson, Ariz., and a site-alteration report was submitted to JPL and Lockheed Martin.
Mehta suggested to the Phoenix science team that they check under its deck on Mars to find exposed ice.
Phoenix landed May 25 on Mars and will spend the next three months analyzing soil and ice to uncover the history of water on the planet. Its mission is to determine whether the arctic plains there could support microbial life.
Renno is a co-investigator on the mission and lead of the Atmospheric Science Theme Group. He is studying the chemical composition of the soil and clouds in effort to determine how much water Mars has today and had in the past. Mehta is currently working on the reconstruction of the mission landing with NASA engineers at JPL.
