's footprint taken during
Apollo 11 shows the fine and powdery texture of the lunar surface. Regolith covers almost the entire
lunar surface,
bedrock protruding only on very steep-sided crater walls and the occasional
lava channel. This regolith has formed over the last 4.6 billion years from the impact of large and small
meteoroids, from the steady bombardment of
micrometeoroids and from solar and galactic charged particles breaking down surface rocks. Regolith production by rock erosion can lead to
fillet buildup around lunar rocks. The impact of micrometeoroids, sometimes travelling faster than , generates enough heat to melt or partially vaporize dust particles. This melting and refreezing welds particles together into glassy, jagged-edged
agglutinates, reminiscent of
tektites found on
Earth. The regolith is generally from 4 to 5 m thick in
mare areas and from 10 to 15 m in the older
highland regions. Below this true regolith is a region of blocky and fractured bedrock created by larger impacts, which is often referred to as the "megaregolith". The density of regolith at the
Apollo 15 landing site () averages approximately 1.35 g/cm3 for the top 30 cm, and it is approximately 1.85g/cm3 at a depth of 60 cm. The term
lunar soil is often used interchangeably with "lunar regolith" but typically refers to the finer fraction of regolith, that which is composed of grains one centimetre in diameter or less. Some have argued that the term "
soil" is not correct in reference to the Moon because soil is defined as having
organic content, whereas the Moon has none. However, standard usage among lunar scientists is to ignore that distinction. "Lunar dust" generally connotes even finer materials than lunar soil, the fraction which is less than 30 micrometers in diameter. The average chemical composition of regolith might be estimated from the relative concentration of elements in lunar soil. The physical and optical properties of lunar regolith are altered through a process known as
space weathering, which darkens the regolith over time, causing
crater rays to fade and disappear. During the early phases of the
Apollo Moon landing program,
Thomas Gold of
Cornell University and part of
President's Science Advisory Committee raised a concern that the thick dust layer at the top of the regolith would not support the weight of the
lunar module and that the module might sink beneath the surface. However, Joseph Veverka (also of Cornell) pointed out that Gold had miscalculated the depth of the overlying dust, which was only a couple of centimeters thick. Indeed, the regolith was found to be quite firm by the robotic
Surveyor spacecraft that preceded Apollo, and during the Apollo landings the astronauts often found it necessary to use a
hammer to drive a
core sampling tool into it. ==Mars==