锰
火星探测计划
土(古典元素)
早期地球
天体生物学
氧化还原
碳酸盐
缺氧水域
化学
碳酸盐矿物
大气(单位)
沉积岩
反应性(心理学)
氧化态
无机化学
大气氧
非生物成分
地质学
氧气
紫外线
矿物学
环境化学
地球化学
光化学
元古代
碱土金属
作者
Jiye Guo,Yuke Zhu,Nicholas J. Tosca,Lu Pan,David C. Catling,Yi Liu,W L Zhang,Amrit S. Chaddha,Pengcheng Ju,Jie Li,Zongbin Zhang,Anya Huo,Yunguo Li,Fang Huang,Paul G. Falkowski,Jihua Hao
标识
DOI:10.1073/pnas.2607260123
摘要
, catalyze oxidative transformations among redox-sensitive metals. Thus, the occurrence of Mn oxides, either observed or inferred from sedimentary geochemical data, has formed the basis for multiple hypotheses concerning the evolution of the atmospheric redox state on the early Earth and Mars. Here, using theory and experiments, we report that the band gap of common Ca/Mg carbonate minerals (including calcite, magnesite, and aragonite) is significantly lowered by trace incorporation (0.8 wt% or lower) of Mn(II) into their bulk structure or surface, conferring photochemical reactivity under ultraviolet conditions relevant to early Earth and Mars (200 to 400 nm). Moreover, we show that surface incorporation of Mn(II) reduces the fundamental band gap much more effectively (by >1 eV) than bulk incorporation. Our results suggest that photo-oxidation of Mn(II)-bearing carbonates could have occurred widely on planetary surfaces, resulting in the abiotic formation of manganese oxides without free molecular oxygen. Photochemically driven redox cycling of manganese could help sustain redox disequilibria for microbial metabolisms, but compromises the use of manganese oxides as oxygen barometers.
科研通智能强力驱动
Strongly Powered by AbleSci AI