Abstract
Abstract Hydrogen is an important energy source for subsurface microbial communities, but its availability beyond the flow focused through hydrothermal chimneys is largely unknown. We report the widespread export of H2 across the Atlantis Massif oceanic core complex (30°N, Mid-Atlantic Ridge; up to 44 nM), which is distinct from the circulation system feeding the Lost City Hydrothermal Field (LCHF) on the massif's southern wall. Methane (CH4) abundances are generally low to undetectable (<3 nM) in fluids that are not derived from the LCHF. Reducing fluids exit the seafloor over a wide geographical area and depth range, including the summit of the massif and along steep areas of mass wasting east of the field. The depth of the fluids in the water column and their H2/CH4 ratios indicate that some are sourced separately from the LCHF. We argue that extensive H2 export is the natural consequence of fluid flow pathways strongly influenced by tectonic features and the volume and density changes that occur when ultramafic rocks react to form serpentinites, producing H2 as a by-product. Furthermore, the circulation of H2-rich fluids through uplifted mantle rocks at moderate temperatures provides geographically expansive and stable environmental conditions for the early evolution of biochemical pathways. These results provide insight into the spatial extent of H2- and CH4-bearing fluids associated with serpentinization, independent of the focused flow emanating from the LCHF.
Highlights
A continuous supply of hydrogen formed by the interaction of water with mantle rocks may have driven the formation of organic molecules on early Earth and other planets, laying the prebiotic groundwork for life (Martin and Russell, 2007; Sojo et al, 2016)
We report the widespread export of H2 across the Atlantis Massif oceanic core complex (MidAtlantic Ridge, 30°N), which is distinct from the circulation system and channeled flow of the nearby Lost City Hydrothermal Field (LCHF)
In 2018, the remotely operated vehicle (ROV) Jason carried out visual seafloor surveys and was outfitted with in situ sensors that continually monitored oxidationreduction potential (ORP) and temperature
Summary
A continuous supply of hydrogen formed by the interaction of water with mantle rocks may have driven the formation of organic molecules on early Earth and other planets, laying the prebiotic groundwork for life (Martin and Russell, 2007; Sojo et al, 2016). We report the widespread export of H2 across the Atlantis Massif oceanic core complex (MidAtlantic Ridge, 30°N), which is distinct from the circulation system and channeled flow of the nearby Lost City Hydrothermal Field (LCHF). This type of decentralized export starkly contrasts with magmatic-dominated systems at mid-ocean ridges where hot, buoyant fluids discharging from depths of ∼1–3 km are channeled into high-permeability up-flow zones (Fisher, 2004; McCaig et al, 2007). The Atlantis Massif decentralized fluids are elevated in H2 and migrate through environments that satisfy multiple requirements for the development of early life
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