https://www.nasa.gov/press-release/goddard/2017/mars-electric-moons
Phobos has been considered as a possible initial base for human exploration of Mars because its weak gravity makes it easier to land spacecraft, astronauts and supplies. The idea would be to have the astronauts control robots on the Martian surface from the moons of Mars, without the considerable time delay faced by Earth-based operators. "We found that astronauts or rovers could accumulate significant electric charges when traversing the night side of Phobos – the side facing Mars during the Martian day," said William Farrell of NASA's Goddard Space Flight Center, Greenbelt, Maryland. "While we don't expect these charges to be large enough to injure an astronaut, they are potentially large enough to affect sensitive equipment, so we would need to design spacesuits and equipment that minimizes any charging hazard." Farrell is lead author of a paper on this research published online Oct. 3 in Advances in Space Research.
[...] The solar wind is responsible for these charging effects. When the solar wind strikes the day side of Phobos, the plasma is absorbed by the surface. This creates a void on the night side of Phobos that the plasma flow is obstructed from directly entering. However, the composition of the wind – made of two types of electrically charged particles, namely ions and electrons – affects the flow. The electrons are over a thousand times lighter than the ions. "The electrons act like fighter jets – they are able to turn quickly around an obstacle -- and the ions are like big, heavy bombers – they change direction slowly," said Farrell. "This means the light electrons push in ahead of the heavy ions and the resulting electric field forces the ions into the plasma void behind Phobos, according to our models."
The study shows that this plasma void behind Phobos may create a situation where astronauts and rovers build up significant electric charges. For example, if astronauts were to walk across the night-side surface, friction could transfer charge from the dust and rock on the surface to their spacesuits. This dust and rock is a very poor conductor of electricity, so the charge can't flow back easily into the surface -- and charge starts to build up on the spacesuits. On the day side, the electrically conducting solar wind and solar ultraviolet radiation can remove the excess charge on the suit. But, on the night side, the ion and electron densities in the trailing plasma void are so low they cannot compensate or 'dissipate' the charge build-up. The team's calculations revealed that this static charge can reach ten thousand volts in some materials, like the Teflon suits used in the Apollo lunar missions. If the astronaut then touches something conductive, like a piece of equipment, this could release the charge, possibly similar to the discharge you get when you shuffle across a carpet and touch a metal door handle.
(Score: 1, Interesting) by Anonymous Coward on Thursday October 19 2017, @05:19PM (3 children)
Can we use that effect for supplying more electric power to our orbital stations then by using photovoltaic panels? Perhaps by using permanent magnets we can make separation of charges in solar wind flux and collect electric charge on separate plates of the apparatus.
(Score: 0) by Anonymous Coward on Thursday October 19 2017, @05:45PM (2 children)
No.
(Score: 2) by DannyB on Thursday October 19 2017, @06:45PM (1 child)
What about charging capacitors from potential differences in charge? Maybe you need a very long wire?
The lower I set my standards the more accomplishments I have.
(Score: 2) by rylyeh on Thursday October 19 2017, @10:41PM
Without a grounding mechanism seems like charging a capacitor or battery would be required.
Tethers into the surface seem impractical.
"a vast crenulate shell wherein rode the grey and awful form of primal Nodens, Lord of the Great Abyss."
(Score: 2) by takyon on Thursday October 19 2017, @05:25PM (2 children)
https://en.wikipedia.org/wiki/Phobos_(moon)#As_part_of_a_manned_mission_to_Mars [wikipedia.org]
At the least, we should send a robotic lander there. Preferably one that can handle this charged dust.
[SIG] 10/28/2017: Soylent Upgrade v14 [soylentnews.org]
(Score: 0) by Anonymous Coward on Friday October 20 2017, @08:44AM (1 child)
What's the point? OK, landing humans on Phobos is easier, but then again, crossing the orbit gap from Phobos to Mars would still be a hard problem. The only thing justifying it would be to bring humans which remotely operate Mars ROVs closer to them, to shorten time lag in control loop.
(Score: 2) by takyon on Friday October 20 2017, @09:29AM
What has NASA committed to doing at Mars in the 2030s? A manned landing? Nope, a manned orbit:
https://www.nasa.gov/content/journey-to-mars-overview [nasa.gov]
Seems to be based on this plan:
http://hom.planetary.org/ [planetary.org]
https://en.wikipedia.org/wiki/Human_mission_to_Mars#Deep_Space_Transport_.282017.29 [wikipedia.org]
Now, overseas or SpaceX developments might cause NASA to change their plans, but that's what's on the agenda right now. A manned orbit of Mars (no landing) around 2033. Landing possible later but no target date stated.
A Phobos orbit or landing should be no worse than a Mars orbit. You could do some surface science there, hopefully without being zapped. Although it would make NASA the butt of many jokes if the U.S. became the first to land on Phobos while another country became the first to land on Mars.
If SpaceX, ULA, Blue Origin, Lockheed Martin, or someone else can beat the Space Launch System to death, maybe we can get a landing by 2035 instead.
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