聚苯乙烯固定化活性炭高效去除水溶液中的铀(VI)和钍(IV)

O. A. Elhefnawy, A. Elabd
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引用次数: 1

摘要

目的制备一种新型聚苯乙烯固定化活性炭(ACPS),用于去除水中的铀(ⅵ)和钍(ⅳ)。活性炭是以生物炭为原料,经化学活化制备而成,以增加其表面活性位点,提高吸附能力。将活性炭(AC)固定在聚苯乙烯(PS)上,以改善活性炭的物理性能并促进其与工作溶液的分离。对新型吸附剂ACPS吸附铀(ⅵ)和钍(ⅳ)的可行性进行了研究。采用吸附动力学、等温线和热力学模型描述了反应机理。设计/方法/途径以生物炭为原料,以2 M H2SO4为溶剂合成活性炭。采用水热法将活性炭固定在预处理聚苯乙烯上,形成新的吸附剂(ACPS)。采用扫描电镜、能量色散x射线能谱仪、红外光谱和x射线衍射技术对其进行了表征。pH、接触时间、料液比、初始浓度和温度等因素对吸附过程有影响。从动力学、等温和热力学三个方面解释了吸附机理。并对废ACPS的再生进行了研究。结果表明,在pHPZC = 3.4时,U(VI)的吸附pH值为6.0 min,吸附平衡时间为60 min, Th(IV)的吸附平衡时间为4.0 min,吸附平衡时间为90 min。实验结果符合拟二级、Freundlich和Dubinin-Radushkevich模型,证明了化学吸附和非均相吸附反应的存在。吸附热力学表明,吸附过程是放热的,具有固/液界面的随机性质。此外,对废ACPS的再生研究表明,该吸附剂具有良好的化学稳定性。对比研究表明,ACPS对U(VI)和Th(IV)的吸附能力高于其他生物吸附剂。原创性/价值本研究通过水热法对从当地市场购买的生物炭进行化学和物理性能的改善,使其成为活性炭。将活性炭固定在聚苯乙烯上,形成吸附水中U(VI)和Th(IV)的新型吸附剂ACPS。
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Highly efficient elimination of uranium (VI) and thorium (IV) from aqueous solution using activated carbon immobilized on polystyrene
Purpose The purpose of this study is to prepare a new adsorbent activated carbon immobilized on polystyrene (ACPS) for uranium (VI) and thorium (IV) removal from an aqueous solution. Activated carbon (AC) was derived from biochar material by chemical activation to increase the active sites on its surface and enhance the adsorption capacity. Activated carbon (AC) was immobilized on polystyrene (PS) to improve the physical properties and facilitate separation from the working solution. A feasibility study for the adsorption of uranium (VI) and thorium (IV) on the new adsorbent (ACPS) has been achieved. Adsorption kinetics, isotherms, and thermodynamics models of the adsorption process were used to describe the reaction mechanism. Design/methodology/approach Activated carbon was synthesized from biochar charcoal by 2 M H2SO4. Activated carbon was immobilized on the pretreatment polystyrene by hydrothermal process forming new adsorbent (ACPS). Characterization studies were carried out by scanning electron microscope, energy-dispersive X-ray spectrometer, infrared spectroscopy and X-ray diffraction techniques. Different factors affect the adsorption process as pH, contact time, solid/liquid ratio, initial concentration and temperature. The adsorption mechanism was explained according to kinetic, isothermal and thermodynamic studies. Also, the regeneration of spent ACPS was studied. Findings The experimental results showed that pH and equilibrium time of the best adsorption were 6.0 and 60 min for U(VI), 4.0 and 90 min for Th(IV), (pHPZC = 3.4). The experimental results fit well with pseudo-second order, Freundlich and Dubinin–Radushkevich models proving the chemisorption and heterogenous adsorption reaction. Adsorption thermodynamics demonstrated that the adsorption process is exothermic and has random nature of the solid/liquid interface. In addition, the regeneration of spent ACPS research showed that the adsorbent has good chemical stability. According to the comparative study, ACPS shows higher adsorption capacities of U(VI) and Th(IV) than other previous bio-adsorbents. Originality/value This study was conducted to improve the chemical and physical properties of bio-charcoal purchased from the local market to activated carbon by hydrothermal method. Activated carbon was immobilized on polystyrene forming new adsorbent ACPS for eliminating U(VI) and Th(IV) from aqueous solutions.
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