Autonomous Rover Drills Underground in the Atacama
Equipped with a drill, cameras, spectrometers and other sensors, for a little over two weeks Zoë analyzed soil samples from above and below the surface. The surface of Mars is considered uninhabitable because of the harsh UV, thin atmosphere, extreme cold and acidic soil, and so many believe the best place to find evidence of past or present life on Mars is deep underground.
This recent excursion with Zoë ended on Saturday, June 29, and it is part of a longer three-year campaign, led by David Wettergreen of Carnegie Mellon University, to test the rover’s instruments and drilling capability. The project is supported through NASA’s ASTEP program to advance the technology and techniques used in planetary exploration.
Thanks to Zoë’s onboard autonomy software, the science team in the United States was able to explore the Atacama remotely, just as NASA mission control would operate a rover on Mars.
The engineering team was in the field with the rover, on hand just in case anything went wrong. Also, “we had a couple people collecting ground truth,” says Wettergreen, “digging pits to make sure what the rover was sampling autonomously was the same as what we’d get on our own.”
“The Raman spectrometer instrument was remarkably robust,” says Wettergreen. Not only was it exposed to a broad range of temperatures, “which is a lot for a laser and detector to take,” he says, “but it got quite a beating over some pretty rocky terrain. Some of the areas we crossed were fairly rugged, so it had to put up with a lot of vibration and shock.”
The rover also has a Bio-UltraViolet Fluorescent instrument (BUF) composed of light-field cameras that can focus at multiple depths. “The UV causes organics to fluoresce, telling us the abundance of organic materials in the samples,” he says.
Zoë made 11 sample drill holes, with samples taken at different depths, resulting in about 40 samples. “Ultimately the science team settled on taking samples from 10 centimeters, then 30 centimeters, and then 80,” says Wettergreen. “The depths were determined on where salt layers formed in the soil, which is a function of how far moisture penetrated.”
Nathalie Cabrol of the SETI Institute, the Science PI for the project, sees the field campaign as a big success -- the rover was highly mobile, traveling up to 10 kilometers per day, and the drill and other instruments worked as they should to gather samples and analyze them. And importantly, all of this was performed autonomously for the first time.
She says that by “punching holes down to 80 centimeters, Zoë can get better access of the record of life on Mars than the MER Opportunity or the MSL Curiosity rovers that are now on Mars.” She says they collected good quality data, and now scientists need time to analyze it all.
One problem that can arise with drilling is contamination of the samples. Wettergreen says this issue was studied intensively in the lab by Honeybee Robotics, the company who made the drill (and also made the drills for MER Opportunity and MSL Curiosity). He says there are two ways to contaminate a drill hole: by moving material at different depths (either up or down the drill column), and transferring material from one drill site to another.
The Honeybee lab tests found that only a small fraction of material moves in the drill column -- instead the force of the drilling process essentially cleans the drill. Although they did not practice this in the field due to the limitations of time, on Mars, a rover would minimize any contamination between sites by drilling a few “waste” holes just to clean off the drill.