环境化学
风化作用
有机质
化学
浸出(土壤学)
成土作用
土壤水分
土壤生产函数
溶解有机碳
土壤有机质
碳酸盐
硅酸盐矿物
土壤科学
总有机碳
中观
硅酸盐
土壤化学
土壤碳
碱土
矿物学
土壤pH值
水分
肥料
吸附
土壤改良剂
土壤肥力
生物炭
固碳
Lessivage公司
阳离子交换容量
粘土矿物
选择性浸出
大块土
作者
Arthur Vienne,Tom Cox,Harun Niron,Bertrand Guenet,Reinaldy Poetra,Laura Steinwidder,Charline Vandenhove,Sara Vicca
标识
DOI:10.1021/acs.est.6c00236
摘要
Key uncertainties remain in predicting carbon sequestration through enhanced weathering (EW), particularly regarding secondary mineral formation and interactions with the organic matter. We compared a coupled inorganic–organic geochemical model (PHREEQCENTURY) with soil measurements and CO 2 efflux from a 389-day mesocosm experiment using soils amended with varying alkaline manure, basalt, and dunite inputs. Silicate amendments did not enhance dissolved inorganic C leaching or significantly increase pedogenic carbonate accumulation. PHREEQC simulations indicated that base cations preferentially precipitated as secondary clays rather than carbonates, inhibiting CO 2 removal. Sequential extractions suggested that Al, Fe and base cations were mainly retained via adsorption to (hydr)oxides and organic matter, with additional retention in secondary clays indicated by models. Higher organic matter addition did not increase element release from basalt─and reduced leached K and Fe─while decreasing the reactive surface area of basalt, indicating a counteractive effect of manure on rock weathering. Alkaline manure addition also likely decreased weathering of pyroxene and olivine minerals. Cumulative soil CO 2 efflux did not differ significantly among treatments, consistent with PHREEQCENTURY simulations, predicting limited treatment effects due to minor changes in soil pH, moisture and organic C stabilization as mineral-associated organic matter in this soil.
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