尾矿
微观世界
环境化学
有机质
化学
生物地球化学循环
成土作用
矿化(土壤科学)
轨道轨道
同位素分析
土壤有机质
生物地球化学
微生物
修正案
溶解有机碳
针铁矿
雪球土
土壤水分
选矿
颗粒有机物
质谱法
生物量(生态学)
矿物
微生物降解
环境科学
稳定同位素比值
沉积有机质
土壤化学
铁矿石
生物矿化
矿物学
赤铁矿
作者
Songlin Wu,Zhen Li,Fang You,Wei Fu,Qi Feng,Guanghui Yu,Cheng-Wei Kao,Ting-Shan Chan,Baodong Chen,Gordon Southam,Longbin Huang
标识
DOI:10.1021/acs.est.5c08638
摘要
Microbial utilization and formation of organic matter (OM) are key driving processes in the eco-engineered pedogenesis in iron (Fe) ore tailings, underpinning sustainable ecological rehabilitation. This four-year microcosm study aimed to unravel the mechanisms of relatively long-term OM transformation and stabilization subject to microbial processing in the OM amended Fe-ore tailings. The method of isotopic tracing (13C-glucose and 13C/15N-labeled spring wheat biomass) and a high-resolution Orbitrap mass spectrometry and nanoscale secondary ion mass spectrometry (NanoSIMS) were employed to characterize molecular composition of OM and organo-microbial-mineral interactions in the resultant tailings technosol at the submicron scale. It was revealed that both soluble (i.e., glucose) and solid (plant biomass) OM used to amend tailings for soil formation generated a diverse range of molecules, including protein-, lipid-, and lignin-like compounds. These organics were predominantly stabilized by Fe- and Al-rich minerals heterogeneously. Meanwhile, microbial 14N2 fixation was observed in tailings primed with 13C-glucose, resulting in microbial OM enriched with 13C and 14N. A dynamic OM turnover in the tailings amended with 13C/15N-labeled spring wheat biomass was observed, which was characterized by the decrease of exogenous 13C/15N and the emergence of organic compounds containing atmospheric sources of 12C/14N. These microbial and mineral-mediated OM formation and stabilization processes indicate the emergence of developing soil ecological resilience, indicated by in situ microorganism-driven C/N biogeochemistry in the initially OM-amended tailings.
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