The problem isn't the hardness of the brush, but the dust. It is harder than any sufficiently lightweight material we could make solar panels out of.

Apparently brushing off the dust would just replace opaque dust with opaque scratches, if the panel isn't already sandblasted to hell to begin with.

Edit: The dust is electrostatically charged and clings to surfaces, so you can't easily tip/blow it off.

A directed blow of air would do nicely I imagine

Show those engineers a NASCAR Race

Because it's very light dust that is electrostatically attached to the panels. Tapping wouldn't do much. And as other folks have mentioned, adding more complexity to the rover means a greater chance of failure and adding more weight, which means more cost, and that you have to choose what other scientific instruments you can't include because you have a maximum weight/cost limit.

You can't just knock the dust off. It's electrostatically charged, so it clings to the panels like a magnet. Additionally, those panels are significantly more delicate than what your average earth-based panel.

I'm pretty sure they're folded up until after landing. Nothing to get scratched on

Spacecraft engineers would love nothing more than to implement all the features they will/might need if they could afford it. When your budget is determined by the government, ya take what you can get

Anything you send to Mars is excruciatingly expensive.

I wonder who is more knowledgeable about this, someone who works with this stuff, or a random redditor? Who looks at a post from someone who knows more about the subject than you explaining the difficulties of something and says "bet it can't be that hard"?

Omg youre so smart. You should apply to help make the rovers. I bet you will be making the next best thing

So the most promising technology NASA has funded for electrostatic displacement of dust in a way amenable to a space environment is called EDS, or an Electrodynamic Screen.

This is essentially a layer that fits over the solar panel with some electrodes embedded in it, patterned in a way that allows us to "walk" dust off the panel using a specific sequence of charge bursts. At first glance this seems like a silver bullet, however this technology has yet to leave the prototyping lab and make it onto a Mars mission for several reasons:

1. Efficiency. The presence of these electrode layers has been found to cut the power output of the panels by 15-25%. This is a no-go, until further developed.
2. Cost. Since this is very new, no industry has developed to marginalize the cost of making these. Since they are essentially still lab prototypes they are still very expensive to make, which makes allotting funding for them kind of tricky. Class B missions (like InSight) have less $$$ available, and Class A flagship missions (like the rovers) are important enough to have an RTG provide power. So at present, this technology is sort of stuck in the middle between function and price; at a certain point you have to ask, if the mission is so important that it *needs* to work long-term, why not just use an RTG? Especially when almost every previous solar panel based mission lasted decades without such a technology.
3. Safety/Reliability. A key point of an EDS is that it produces charge using voltages in the kV level. This runs the risk of arcing/damage at a certain point (Paschen's breakdown for the engineers). The breakdown voltage at which an arc forms depends a lot on the atmosphere, and we simply need further research into the composition of Mars dust in order to safely design an EDS that guarantees minimal risk of arcing.

TL;DR - It'll get there, it's not there yet.

My father worked for JPL for 40+ years, and no, they really don't. What they do is make the projected lifespan as guaranteed as possible. A happy side effect of that is these great extended-mission lifespan, but the goal is hitting the primary lifespan securely.

No, it is an artificat of designing for a high sucess probability. For a simple example, let's say you want a robot for a 1 year mission with 90% probability of it lasting two years. You design the robot so that it has a failure rate of 5% per year. As a result it is highly likely (~80%) that it will last four years or twice the required mission length.

Obviously this is a very simplified example, but hopefully it illustrates the point that you cannot easily determine the exactly lifespan of a piece of equipment.

"Cheaper" doesn't matter when you have X budget, and if you don't spend it, you'll have a smaller budget the next year because you obviously didn't need that much.

That's not really how this works.

These things have a specified lifetime of e.g. 2 years. That means, each component is built and designed to last 2 years with a probability of 99,9%. That in turn means, that there's a high likelihood for the device to survive much longer then two years. Adding additional safety margins for a designed lifetime of 4 years will make the whole thing much more expensive and maybe even less capable, simply because it's going to be heavier.

And additionally, NASA engineers often enough hack devices to work much longer. The Kepler telescope for example had one too many reaction wheels fail and was thought to be dead, but some clever engineer find a way to use the remaining ones to still do some science.

Did you mean to say "more than"?
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