Emerging investigator series: Coprecipitation with glucuronic acid limits reductive dissolution and transformation of ferrihydrite in an anoxic soil†

IF 4.3 3区 环境科学与生态学 Q1 CHEMISTRY, ANALYTICAL
Laurel K. ThomasArrigo, Luiza Notini, Sophie Vontobel, Sylvain Bouchet, Tabea Nydegger and Ruben Kretzschmar
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Abstract

Ferrihydrite, a poorly crystalline Fe(III)-oxyhydroxide, is abundant in soils and is often found associated with organic matter. Model studies consistently show that in the presence of aqueous Fe(II), organic carbon (OC)-associated ferrihydrite undergoes less transformation than OC-free ferrihydrite. Yet, these findings contrast microbial reductive dissolution studies in which the OC promotes the reductive dissolution of Fe(III) in ferrihydrite and leads to the release of associated OC. To shed light on these complex processes, we quantified the extent of reductive dissolution and transformation of native Fe minerals and added ferrihydrite in anoxic soil incubations where pure 57Fe-ferrihydrite (57Fh), pure 57Fe-ferrihydrite plus dissolved glucuronic acid (57Fh + GluCaq), a 57Fe-ferrihydrite-13C-glucuronic acid coprecipitate (57Fh13GluC), or only dissolved glucuronic acid (13GluCaq) were added. By tracking the transformation of the 57Fe-ferrihydrite in the solid phase with Mössbauer spectroscopy together with analysis of the iron isotope composition of the aqueous phase and chemical extractions with inductively coupled plasma-mass spectrometry, we show that the pure 57Fe-ferrihydrite underwent more reductive dissolution and transformation than the coprecipitated 57Fe-ferrihydrite when identical amounts of glucuronic acid were provided (57Fh + GluCaqversus57Fh13GluC treatments). In the absence of glucuronic acid, the pure 57Fe-ferrihydrite underwent the least reductive dissolution and transformation (57Fh). Comparing all treatments, the overall extent of Fe(III) reduction, including the added and native Fe minerals, determined with X-ray absorption spectroscopy, was highest in the 57Fh + GluCaq treatment. Collectively, our results suggest that the limited bioavailability of the coprecipitated OC restricts not only the reductive dissolution of the coprecipitated mineral, but it also limits the enhanced reduction of native soil Fe(III) minerals.

Abstract Image

Abstract Image

新晋研究员系列:葡萄糖醛酸共沉淀限制了缺氧土壤中铁hydrite的还原溶解和转化。
铁水物是一种结晶性很差的氧化铁(III)-氢氧化物,在土壤中含量丰富,通常与有机物伴生。模型研究一致表明,在铁(II)水溶液存在的情况下,有机碳(OC)伴生的无水铁比不含有机碳的无水铁发生的转化要少。然而,这些发现与微生物还原溶解研究形成了鲜明对比,在微生物还原溶解研究中,有机碳促进了铁氧体中铁(III)的还原溶解,并导致了相关有机碳的释放。为了揭示这些复杂的过程,我们量化了原生铁矿物的还原溶解和转化程度,以及在缺氧土壤培养中添加纯 57Fe-ferrihydrite (57Fh)的铁水物的还原溶解和转化程度、纯 57Fe-ferrihydrite 加上溶解的葡萄糖醛酸(57Fh + GluCaq)、57Fe-ferrihydrite-13C-葡萄糖醛酸共沉淀(57Fh13GluC)或仅溶解的葡萄糖醛酸(13GluCaq)。通过用莫斯鲍尔光谱仪跟踪固相中 57Fe-ferrihydrite 的转化,同时分析水相中的铁同位素组成,并用电感耦合等离子体质谱仪进行化学萃取,我们发现在提供相同量的葡萄糖醛酸时,纯 57Fe-ferrihydrite 比共沉 57Fe-ferrihydrite 经历了更多的还原溶解和转化(57Fh + GluCaq 对 57Fh13GluC 处理)。在没有葡萄糖醛酸的情况下,纯 57Fe-ferrihydrite 的还原溶解和转化(57Fh)最小。通过 X 射线吸收光谱测定,比较所有处理,57Fh + GluCaq 处理的铁(III)还原程度(包括添加的和原生的铁矿物)最高。总之,我们的研究结果表明,共沉淀 OC 的生物利用率有限,这不仅限制了共沉淀矿物的还原溶解,而且还限制了土壤中原生铁(III)矿物的还原增强。
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来源期刊
Environmental Science: Processes & Impacts
Environmental Science: Processes & Impacts CHEMISTRY, ANALYTICAL-ENVIRONMENTAL SCIENCES
CiteScore
9.50
自引率
3.60%
发文量
202
审稿时长
1 months
期刊介绍: Environmental Science: Processes & Impacts publishes high quality papers in all areas of the environmental chemical sciences, including chemistry of the air, water, soil and sediment. We welcome studies on the environmental fate and effects of anthropogenic and naturally occurring contaminants, both chemical and microbiological, as well as related natural element cycling processes.
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