自然发生
早期地球
甲烷
铁质
天体生物学
化学
缺氧水域
硫黄
非生物成分
环境化学
氮气
土(古典元素)
太古宙
氧气
商品化学品
光化学
催化作用
有机化学
生态学
生物
地质学
地球化学
物理
数学物理
作者
Leonard Ernst,Uladzimir Barayeu,Jonas Hädeler,Tobias P. Dick,Judith M. Klatt,Frank Keppler,Johannes G. Rebelein
标识
DOI:10.1038/s41467-023-39917-0
摘要
Abstract Methane is a potent greenhouse gas, which likely enabled the evolution of life by keeping the early Earth warm. Here, we demonstrate routes towards abiotic methane and ethane formation under early-earth conditions from methylated sulfur and nitrogen compounds with prebiotic origin. These compounds are demethylated in Fenton reactions governed by ferrous iron and reactive oxygen species (ROS) produced by light and heat in aqueous environments. After the emergence of life, this phenomenon would have greatly intensified in the anoxic Archean by providing methylated sulfur and nitrogen substrates. This ROS-driven Fenton chemistry can occur delocalized from serpentinization across Earth’s humid realm and thereby substantially differs from previously suggested methane formation routes that are spatially restricted. Here, we report that Fenton reactions driven by light and heat release methane and ethane and might have shaped the chemical evolution of the atmosphere prior to the origin of life and beyond.
科研通智能强力驱动
Strongly Powered by AbleSci AI