Mimicking lightning-induced electrochemistry on the early Earth.
Haihui Joy JiangThomas C UnderwoodJeffrey G BellJonathan LeiJoe C GonzalesLukas EmgeLeah G TadeseMohamed K Abd El-RahmanDavid M WilmouthLaís Canniatti BrazacaGigi NiGeorge M WhitesidesSupriya DeyAli Akbar AshkarranAmit NagarkarMarkus P NemitzBrian J CaffertyDavid S SayresSukrit RanjanDaniel R CrockerJames G AndersonDimitar D SasselovGeorge M WhitesidesPublished in: Proceedings of the National Academy of Sciences of the United States of America (2024)
To test the hypothesis that an abiotic Earth and its inert atmosphere could form chemically reactive carbon- and nitrogen-containing compounds, we designed a plasma electrochemical setup to mimic lightning-induced electrochemistry under steady-state conditions of the early Earth. Air-gap electrochemical reactions at air-water-ground interfaces lead to remarkable yields, with up to 40 moles of carbon dioxide being reduced into carbon monoxide and formic acid, and 3 moles of gaseous nitrogen being fixed into nitrate, nitrite, and ammonium ions, per mole of transmitted electrons. Interfaces enable reactants (e.g., minerals) that may have been on land, in lakes, and in oceans to participate in radical and redox reactions, leading to higher yields compared to gas-phase-only reactions. Cloud-to-ground lightning strikes could have generated high concentrations of reactive molecules locally, establishing diverse feedstocks for early life to emerge and survive globally.