Clemente Joyce S, Beauchemin Suzanne, MacKinnon Ted, Martin Joseph, Johnston Cliff T, Joern Brad
Natural Resources Canada, CanmetMINING, 555 Booth Street, Ottawa, Ontario, K1A 0G1, Canada.
Natural Resources Canada, CanmetMINING, 555 Booth Street, Ottawa, Ontario, K1A 0G1, Canada.
Chemosphere. 2017 Mar;170:216-224. doi: 10.1016/j.chemosphere.2016.11.154. Epub 2016 Dec 19.
This study tests the influence of a diverse set of biochar properties on As(V), Se(IV), Cd(II), Cu(II), Ni(II), Pb(II), or Zn(II) removal from solution at pH 4.5. Six commercial biochars produced using different feedstock and pyrolysis conditions were extensively characterized using physical, chemical, and spectroscopic techniques, and their properties were correlated to anion and cation removal using multiple linear regression. H/total organic C (TOC) ratio and volatile matter were positively correlated to cation removal from solution, which indicate interactions between metals and non-aromatic C. Defining the correlation of ion removal with specific OC functional groups was hindered by the inherent limitations of the spectroscopic techniques, which was exacerbated by the heterogeneity of the biochars. Ash was negatively correlated to Se(IV) and positively correlated to Cd(II), Cu(II), and Ni(II) removal from solution. Interference from soluble P in biochars may partly explain the low Se(IV) removal from solution; and Ca-, P-, and Fe- containing compounds likely sorbed or precipitated Pb(II), Cd(II), Cu(II), Ni(II) and Zn(II). Furthermore, Ca-oxalate identified using X-ray diffraction in willow, may be responsible for willow's increased ability to remove Cd(II), Ni(II), and Zn(II) compared to the other 5 biochars. It was clear that both OC and inorganic biochar components influenced metal(loid) and Se(IV) removal from solution. The non-aromatic and volatile OC correlated to removal from solution may be readily available for microbial degradation, while Mg, N, P, and S are required for biological growth. Biological metabolism and uptake of these compounds may inhibit or destabilize their interaction with contaminants.
本研究测试了一系列不同生物炭性质对在pH 4.5条件下从溶液中去除砷(V)、硒(IV)、镉(II)、铜(II)、镍(II)、铅(II)或锌(II)的影响。使用不同原料和热解条件生产的六种商业生物炭,通过物理、化学和光谱技术进行了广泛表征,并使用多元线性回归将它们的性质与阴离子和阳离子去除相关联。氢与总有机碳(TOC)的比率和挥发物与从溶液中去除阳离子呈正相关,这表明金属与非芳香族碳之间存在相互作用。光谱技术的固有局限性阻碍了确定离子去除与特定有机碳官能团之间的相关性,而生物炭的异质性加剧了这种局限性。灰分与从溶液中去除硒(IV)呈负相关,与从溶液中去除镉(II)、铜(II)和镍(II)呈正相关。生物炭中可溶性磷的干扰可能部分解释了从溶液中去除硒(IV)的效率较低的原因;含钙、磷和铁的化合物可能吸附或沉淀了铅(II)、镉(II)、铜(II)、镍(II)和锌(II)。此外,通过X射线衍射在柳树生物炭中鉴定出的草酸钙,可能是柳树生物炭相比于其他5种生物炭去除镉(II)、镍(II)和锌(II)能力增强的原因。很明显,有机碳和生物炭的无机成分都影响了从溶液中去除金属(类金属)和硒(IV)。与从溶液中去除相关的非芳香族和挥发性有机碳可能易于被微生物降解,而生物生长需要镁、氮、磷和硫。这些化合物的生物代谢和吸收可能会抑制或破坏它们与污染物的相互作用。
