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These questions and their answers address some potential aspects of a rover on Saturn's moon Titan.

The abstract to the new paper in Nature Observational evidence for active dust storms on Titan at equinox begins:

Saturn’s moon Titan has a dense nitrogen-rich atmosphere, with methane as its primary volatile. Titan’s atmosphere experiences an active chemistry that produces a haze of organic aerosols that settle to the surface and a dynamic climate in which hydrocarbons are cycled between clouds, rain and seas. Titan displays particularly energetic meteorology at equinox in equatorial regions, including sporadic and large methane storms. In 2009 and 2010, near Titan’s northern spring equinox, the Cassini spacecraft observed three distinctive and short-lived spectral brightenings close to the equator. Here, we show from analyses of Cassini spectral data, radiative transfer modelling and atmospheric simulations that the brightenings originate in the atmosphere and are consistent with formation from dust storms composed of micrometre-sized solid organic particles mobilized from underlying dune fields.

Our fearless rover will either get rained on aerosol-settled-on by stuff similar to the stuff that's already in the lakes. While radar images show it as black, I'm guessing that it's probably fairly transparent, and this answer indicates that the bulk of the liquid is not expected to be oily but being mostly methane, much lower viscosity than water. However, any less volatile materials present in the rain might conceivably begin build up, and then attract dust and dirt.

Will the rover be sticky from this? Will instruments get covered in this, and then potentially a dust storm will come by and coat it with an additional layer of dirt?

Will cameras and other sensors need protective covers that only open a short time for data-taking? Will the headlights need windshield-wipers?

For more info on Titan conditions see for example these and their answers:

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  • $\begingroup$ I'm quite sure it's black in visible spectrum - the composition would be quite similar to crude oil. $\endgroup$ – SF. Sep 26 '18 at 6:43
  • $\begingroup$ hydrogenless carbons, a.k.a. soot... $\endgroup$ – SF. Sep 27 '18 at 11:31
  • $\begingroup$ In realistic crude oils (of any kind) you get a huge number of varied hydrocarbons in all possible configurations. 0 hydrogens 1 or more carbon is an allowed configuration that happens alongside the rest. In normal earthly soot you won't find hydrogen because small hydrocarbons are volatile while carbon alone forms a solid, plus hydrogen will bind with other substances easier than carbon and forming more stable bonds, so e.g. burning hydrocarbons with deficiency of oxygen, you get water, carbon monoxide and soot, not carbon dioxide and loose hydrogen. $\endgroup$ – SF. Sep 27 '18 at 12:17
  • $\begingroup$ I don't know how Titan's hydrocarbons formed. If there was excess of hydrogen, it's possible there would be very little unbound carbon. If it was abundant but the carbon was taken from other compounds, it would be possible excess remained in these compounds. But if you react carbon+hydrogen with deficiency of hydrogen, you get some surplus soot. $\endgroup$ – SF. Sep 27 '18 at 12:19
  • $\begingroup$ Let us continue this discussion in chat. $\endgroup$ – uhoh Sep 27 '18 at 13:36

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