After the primary hydrogen atmosphe

After the primary hydrogen atmosphere of Earth had escaped into space, the socalled
secondary atmosphere built up with volcanic gases; this atmosphere was,
most likely, dominated by CO2, with smaller amounts of N2, CO, and H2, similar
to that on modern Mars and Venus, where CO2 still makes up 95% of the atmosphere
[25,93-100]. As the Earth’s surface gradually cooled, water vapour started
to condense into the first oceans. The atmospheric pressure at the surface of primordial
Earth has been estimated to reach several hundred bars; therefore ocean
formation could have started when the surface was still very hot [94,97,100].
Zircon data indicate the presence of the first continent(s) by 4.2 Ga [188]. Hydrothermal
activity of some type would have been established promptly, driven
by thermal convection. Most likely, the initial convection systems did not form
a continuous chain of mid-ocean ridges as they do now but a pattern of “hot
spots” similar to modern volcanic island arcs [93,95,189]. The activity of these
hydrothermal/volcanic systems was accompanied by surges of hot hydrothermal
fluids to the surface. Owing to the initial atmospheric pressure of ≥ 100 bar (see
[94,100], and cf. with the pressure of 95 bar at the surface of modern Venus), very
hot hydrothermal fluids enriched by dissolved metals could discharge directly to
the surface of the first continents. This situation differed fundamentally from
the modern one, since today such hot fluids can reach the continental surface
only as steam (at the points of volcanic or geyser activity), losing their metal
content on the way. Taking into account the slow precipitation of ZnS under
high-pressure conditions [183] and the abundance of Zn in the Earth’s crust [90],