On airless bodies, electrostatic transport is believed to be the leading cause of dust transport.
Infrared rays and
ultraviolet rays from the Sun are strong enough to knock electrons off the dust present on surface. These positively charged particles get repelled from the surface kilometers high. On the night side, the dust is negatively charged by electrons from the
solar wind. Particles at the night side would achieve greater
electrical tension differences than the day side, launching dust particles to even higher altitudes. Laboratory experiments show that dusty surfaces tend to become smooth as a result of dust mobilization. When these levitated dust travels into a shadowed region, they lose their charge and fall to the ground. Over time, dust accumulate on such places. This is believed to be the leading cause of Dust ponds. However, the precise mechanics of electrostatic dust launching remain mysterious. The high obliquity of
Eros (88°) results in low latitudes spending more time with the Sun near the horizon than higher latitudes. This results in more dust ponds in the equatorial region. Electrostatically levitated dust is believed to be the cause of a phenomenon named
lunar horizon glow, where such particles scatter sunlight during lunar sunset, creating a shining horizon. . Photo taken by
Surveyor 7 mission. Apart from this, seismic shaking,
outgassing, and fluidization is also believed to be the cause, although all of these theories contain some flaws. Fluidization of impact ejecta is believed to be the cause of structures named melt pools on moon. This results is two types of dust ponds, that of impact melt (type 1) and that of (Dust accumulation). Type 1 ponds are located near the impact melt of large craters. The dust is uniformly distributed across the crater floor, producing smooth pond surfaces with a constant slope and shallow depth. The dust ponds however, have a less constant slope. Type 2 ponds are rare in moon because more electrostatic tension is needed to overcome the gravitational pull of the moon. In asteroids with low gravity, less electrostatic difference is needed, resulting in more type-2 dust ponds. The variation in
albedo is thought to be due to mineral heterogeneity, or the difference in grain size. The material is distributed in the crater with a slight offset in the geometric center. Particles in the dust ponds are also rich in Silicate materials (
olivine and pyroxenes). The slight blue color of the pond deposits is due to a property of
mafic materials that makes them visibly bluer at very fine grain sizes (≤50 μm) due to changes in packing. Overall, ponds are formed in planetary bodies with dry brittle
regolith or low volatile content. ==Examples==