通过生物改性的生物炭从玉米秸秆青贮消化残渣中去除水溶液中的 Cd。

Enhanced Cd removal from aqueous solution by biologically modified biochar derived from digestion residue of corn straw silage.

机构信息

College of Resources, Sichuan Agricultural University, Chengdu 611130, China.

College of Horticulture, Sichuan Agricultural University, Chengdu 611130, China.

出版信息

Sci Total Environ. 2019 Jul 15;674:213-222. doi: 10.1016/j.scitotenv.2019.03.438. Epub 2019 Mar 29.

DOI:10.1016/j.scitotenv.2019.03.438

PMID:31004898

Abstract

Biologically modified biochars derived from digestion residue of corn straw silage at different pyrolysis temperature (300-700 °C) were prepared for removing Cd from water. Compared with the pristine biochar derived from corn straw (CB), transabdominal transformation of corn straw silage (TCB) significantly increased surface area (4.24-56.58 m g), oxygen-containing functional group (COC, MgO, SiO) and mineral components (CaCO, KCl). The sorption isotherms could be well described by Langmuir model, the kinetic data was best fitted by the Pseudo second order model. The maximum sorption capacity (Qm) obtained from Langmuir model for TCB700 (175.44 mg g) was 3 times of CB700 (56.82 mg g). Precipitation with minerals, ion exchange and complexation with oxygen-containing functional groups were the main mechanisms of Cd(II) sorption on TCB. These results imply that biologically modified biochar derived from digestion residue of corn straw silage at ≥600 °C is an effective sorbent for Cd removal from water.

摘要

不同热解温度（300-700°C）下从玉米青贮消化残渣中制备的生物改性生物炭用于去除水中的 Cd。与来源于玉米秸秆的原始生物炭（CB）相比，玉米青贮的经腹转化（TCB）显著增加了表面积（4.24-56.58 m²/g）、含氧量官能团（COC、MgO、SiO）和矿物质成分（CaCO、KCl）。吸附等温线可以很好地用朗缪尔模型描述，动力学数据用伪二级模型拟合最好。从 Langmuir 模型获得的 TCB700（175.44 mg/g）的最大吸附容量（Qm）是 CB700（56.82 mg/g）的 3 倍。矿物沉淀、离子交换和含氧官能团络合是 Cd(II)在 TCB 上吸附的主要机制。这些结果表明，来源于玉米青贮消化残渣、热解温度≥600°C 的生物改性生物炭是一种从水中去除 Cd 的有效吸附剂。

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通过生物改性的生物炭从玉米秸秆青贮消化残渣中去除水溶液中的 Cd。

Enhanced Cd removal from aqueous solution by biologically modified biochar derived from digestion residue of corn straw silage.

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