生物炭
吸附
弗伦德利希方程
镉
化学
环境修复
水溶液
朗缪尔
稻草
核化学
壳聚糖
污染
朗缪尔吸附模型
废水
受污染的水
环境化学
环境工程
环境科学
有机化学
无机化学
热解
生物
生态学
作者
Yasir Hamid,Lei Liu,Muhammad Haris,Muhammad Usman,Qiang Lin,Yong-Long Chen,Muhammad Rashid,Zaid Ulhassan,Muhammad Iftikhar Hussain,Xiaoe Yang
标识
DOI:10.1016/j.jece.2023.110527
摘要
This study followed the one-step and two-step technologies to produce rice straw biochar (BC), chitosan-modified rice straw biochar (CT-BC), and thiol grafted chitosan-modified biochar (TH@CT-BC) for cadmium (Cd) removal from contaminated water. Here, chitosan and thiol were introduced by two-step combination to enhance the adsorption ability of biochar. Our results revealed the maximum Cd adsorption at pH 5.5 with TH@CT-BC (261.47 mg g −1 ) followed by CT-BC (103.14 mg g −1 ) and BC (29.64 mg g −1 ). Obtained data was best fitted by the Langmuir and pseudo-second-order kinetic models (with R 2 values of 0.997 for TH@CT-BC) as compared to Freundlich and Temkin models (0.949 and 0.925, respectively). TH@CT-BC retained its efficiency in spiked river water system, removing up to 89% of Cd in river water spiked with 30 mg −1 L Cd. The experimental investigations and data calculations demonstrated the surface complexation and electrostatic interaction as dominant underlying mechanisms for Cd removal by TH@CT-BC. Moreover, it is essential to utilize the large amount of produced rice straw to develop new materials which would help in converting the waste to useable product for environmental remediation. Thus, this study demonstrates the production of TH@CT-BC from rice straw as an effective adsorbent of Cd from aqueous systems which can be studied as a potential candidate for practical wastewater treatment applications.
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