腐植酸对氧化锌吸附Cu(Ⅱ)的影响

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摘要

为研究复杂三元体系中HA（Humic acid，腐殖酸）对氧化锌吸附Cu（Ⅱ）的影响，探究HA对重金属Cu（Ⅱ）在环境中迁移转化的作用机理，通过改变HA的添加顺序及添加量，系统研究了HA在不同环境条件下对氧化锌吸附Cu（Ⅱ）的影响作用.结果表明，添加HA能显著降低氧化锌对Cu（Ⅱ）的吸附量，在pH为5.05时添加50mg/L的HA，Cu（Ⅱ）的最大吸附量降低了61.74%；离子强度增大会促进氧化锌对Cu（Ⅱ）的吸附，在NaNO₃浓度为1.0mol/L时最大吸附量为21.79mg/g；pH值为5.05时吸附量达到最大值，升温有利于氧化锌对Cu（Ⅱ）吸附，氧化锌对Cu（Ⅱ）的吸附符合Freundlich模型.HA不同添加顺序对Cu（Ⅱ）的吸附量的影响表现为对照>后添加HA >同时添加HA >先添加HA.红外光谱特征表明，HA和Cu（Ⅱ）在氧化锌表面吸附位点形成竞争吸附，并且氧化锌表面的羟基在吸附HA和Cu（Ⅱ）的过程中产生重要作用.

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	谢发之
	谢志勇
	李国莲
	李海斌
	汪雪春
	岳先名
	李振宇

关键词 ：腐植酸, 氧化锌, Cu(Ⅱ), 吸附

Abstract：

To study the influence of humic acid on the adsorption of Cu (Ⅱ) by zinc oxide, the adsorption of Cu (Ⅱ) on zinc oxide in different environment conditions were investigated, by changing the order of addition and dosage of HA. The mechanism of fate and transport of Cu (Ⅱ) in the water environment was also proposed. The results showed that the adsorption Cu(Ⅱ) on zinc oxide could be significantly reduced by adding HA, and that the Cu (Ⅱ) maximum adsorption decreased 61.74% by adding 50mg/L HA in the pH of 5.05. The Cu (Ⅱ) adsorption increased by increasing the ionic strength, the maximum adsorption was 21.79mg/g when the concentration of NaNO₃ was 1.0mol/L. When the pH value was 5.05 the adsorption reached the maximum; and temperature was in favor of Cu (Ⅱ) adsorption on zinc oxide. Cu (Ⅱ) adsorption on zinc oxide fitted the Freundlich model well. The adding orders of HA influence the Cu (Ⅱ) adsorption as the following:non-adding > adding after > adding simultaneously > adding ahead. The characteristics of infrared spectra showed that HA and Cu (Ⅱ) form competitive adsorption on the surface adsorption and surface hydroxyl of zinc oxide play an important role in adsorption of HA and Cu (Ⅱ).

Key words： humic acid zinc oxide copper (Ⅱ) adsorption

收稿日期: 2017-02-02

PACS:

X703.1

基金资助:

安徽省自然科学基金项目（1608085MB43）；国家自然基金项目（21107001）；安徽省教育厅自然科学研究重点项目（KJ2016A154）；安徽省2014年高校优秀青年人才支持计划项目

通讯作者: 谢发之,教授,fzxie@ahjzu.edu.cn E-mail: fzxie@ahjzu.edu.cn

作者简介: 谢发之(1976-),男,安徽定远人,教授,博士,主要从事环境污染控制方面的研究.发表论文50余篇.

引用本文:

谢发之, 谢志勇, 李国莲, 李海斌, 汪雪春, 岳先名, 李振宇. 腐植酸对氧化锌吸附Cu(Ⅱ)的影响[J]. 中国环境科学, 2017, 37(8): 2970-2977. XIE Fa-zhi, XIE Zhi-yong, LI Guo-lian, LI Hai-bin, WANG Xue-chun, YUE Xian-ming, LI Zhen-yu. Effects of humic acid on the adsorption of copper (Ⅱ) onto zinc oxide. CHINA ENVIRONMENTAL SCIENCECE, 2017, 37(8): 2970-2977.

链接本文:

http://manu36.magtech.com.cn/Jweb_zghjkx/CN/ 或 http://manu36.magtech.com.cn/Jweb_zghjkx/CN/Y2017/V37/I8/2970

[1]	Chen C S, Chen S. Adsorption of Pesticidal Compounds Bearing a Single Carboxyl Functional Group and Biogenic Amines by Humic Fraction-Immobilized Silica Gel[J]. Journal of agricultural and food chemistry, 2013,61(15):3600-3610.
[2]	Guo X, Tu B, Ge J, et al. Sorption of tylosin and sulfamethazine on solid humic acid[J]. Journal of Environmental Sciences, 2016,43:208-215.
[3]	Ji H, Wu G, Zi M, et al. Microsecond Molecular Dynamics Simulation of Methane Hydrate Formation in Humic-AcidAmended Sodium Montmorillonite[J]. Energy & Fuels, 2016, 30(9):7206-7213.
[4]	Hao L, Chen L, Hao J, et al. Bioaccumulation and sub-acute toxicity of zinc oxide nanoparticles in juvenile carp (Cyprinus carpio):a comparative study with its bulk counterparts[J]. Ecotoxicology and environmental safety, 2013,91:52-60.
[5]	Sheela T, Nayaka Y A, Viswanatha R, et al. Kinetics and thermodynamics studies on the adsorption of Zn (Ⅱ), Cd (Ⅱ) and Hg (Ⅱ) from aqueous solution using zinc oxide nanoparticles[J]. Powder Technology, 2012,217:163-170.
[6]	Zheng X, Wu R, Chen Y G, et al. Effects of ZnO nanoparticles on wastewater biological nitrogen and phosphorous removal[J]. Environmental Science & Technology, 2011,45(7):2826-2832.
[7]	冯启言,张彦,孟庆俊,煤矿区废水中溶解性有机质与铜的结合特性[J]. 中国环境科学, 2013,33(8):1433-1441.
[8]	龙良俊,王里奥,余纯丽,等.改性污泥腐殖酸的表征及其对Cu2+的吸附特性[J]. 中国环境科学, 2017,37(3):1016-1023.
[9]	Kim H, Jeong H, Byeon S H. Selective filter effect induced by Cu2+ adsorption on the fluorescence of a GdVO4:Eu nanoprobe[J]. ACS applied materials & interfaces, 2016:15497-15505.
[10]	Zhu X, Shan Y, Xiong S, et al. Brianyoungite/Graphene Oxide Coordination Composites for High-Performance Cu2+ Adsorption and Tunable Deep-Red Photoluminescence[J]. ACS applied materials & interfaces, 2016:15848-15854.
[11]	Bagheri M, Azizian S, Jaleh B, et al. Adsorption of Cu (Ⅱ) from aqueous solution by micro-structured ZnO thin films[J]. Journal of Industrial and Engineering Chemistry, 2014,20(4):2439-2446.
[12]	Yang K, Miao G, Wu W, et al. Sorption of Cu2+ on humic acids sequentially extracted from a sediment[J]. Chemosphere, 2015, 138:657-663.
[13]	Bian S W, Mudunkotuwa I A, Rupasinghe T, et al. Aggregation and dissolution of 4nm ZnO nanoparticles in aqueous environments:influence of pH, ionic strength, size, and adsorption of humic acid[J]. Langmuir, 2011,27(10):6059-6068.
[14]	Mittal H, Maity A, Sinha Ray S. The adsorption of Pb2+ and Cu2+ onto gum ghatti-grafted poly (acrylamide-co-acrylonitrile) biodegradable hydrogel:isotherms and kinetic models[J]. The Journal of Physical Chemistry B, 2015,119(5):2026-2039.
[15]	Wang J, Li X. Ion-imprinted composite hydrogels with excellent mechanical strength for selective and fast removal of Cu2+[J]. Industrial & Engineering Chemistry Research, 2012,52(2):572-577.
[16]	Li Y, Yue Q, Gao B. Adsorption kinetics and desorption of Cu (Ⅱ) and Zn (Ⅱ) from aqueous solution onto humic acid[J]. Journal of hazardous materials, 2010,178(1):455-461.
[17]	Lin D, Tian X, Li T, et al. Surface-bound humic acid increased Pb2+ sorption on carbon nanotubes[J]. Environmental pollution, 2012,167:138-147.
[18]	Sibanda H M, Young S D. Competitive adsorption of humic acids and phosphate on goethite, gibbsite and two tropical soils[J]. European Journal of Soil Science, 1986,37(2):197-204.
[19]	Wang L, Han C, Nadagouda M N, et al. An innovative zinc oxide-coated zeolite adsorbent for removal of humic acid[J]. Journal of hazardous materials, 2016,313:283-290.
[20]	Karlsson T, Persson P, Skyllberg U. Complexation of copper (Ⅱ) in organic soils and in dissolved organic matter-EXAFS evidence for chelate ring structures[J]. Environmental science & technology, 2006,40(8):2623-2628.
[21]	Hayes K F, Papelis C, Leckie J O. Modeling ionic strength effects on anion adsorption at hydrous oxide/solution interfaces[J]. Journal of Colloid and Interface Science, 1988,125(2):717-726.
[22]	Wang X, Cai W, Lin Y, et al. Mass production of micro/nanostructured porous ZnO plates and their strong structurally enhanced and selective adsorption performance for environmental remediation[J]. Journal of Materials Chemistry, 2010,20(39):8582-8590.
[23]	Akhil K, Chandran P, Khan S S. Influence of humic acid on the stability and bacterial toxicity of zinc oxide nanoparticles in water[J]. Journal of Photochemistry and Photobiology B:Biology, 2015,153:289-295.
[24]	Senesi N. Molecular and quantitative aspects of the chemistry of fulvic acid and its interactions with metal ions and organic chemicals:Part Ⅱ. The fluorescence spectroscopy approach[J]. Analytica Chimica Acta, 1990,232:77-106.
[25]	Klu?áková M, Kalina M. Diffusivity of Cu (Ⅱ) ions in humic gels-influence of reactive functional groups of humic acids[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects, 2015,483:162-170.
[26]	Villaescusa I, Fiol N, Martinez M, et al. Removal of copper and nickel ions from aqueous solutions by grape stalk wastes[J]. Water Research, 2004,38(4):992-1002.
[27]	Ballerini G, Ogle K, Barthés-Labrousse M G. The acid-base properties of the surface of native zinc oxide layers:an XPS study of adsorption of 1, 2-diaminoethane[J]. Applied surface science, 2007,253(16):6860-6867.
[28]	Degen A, Kosec M. Effect of pH and impurities on the surface charge of zinc oxide in aqueous solution[J]. Journal of the European Ceramic Society, 2000,20(6):667-673.
[29]	Doyle F M, Liu Z. The effect of triethylenetetraamine (Trien) on the ion flotation of Cu2+ and Ni2+[J]. Journal of colloid and interface science, 2003,258(2):396-403.
[30]	Zhou Y T, Nie H L, Branford-White C, et al. Removal of Cu2+ from aqueous solution by chitosan-coated magnetic nanoparticles modified with α-ketoglutaric acid[J]. Journal of Colloid and Interface Science, 2009,330(1):29-37.
[31]	Lee S J, Chung S G, Kim D J, et al. New method for determination of equilibrium/kinetic sorption parameters[J]. Current Applied Physics, 2009,9(6):1323-1325.
[32]	Lin J, Zhan Y, Zhu Z. Adsorption characteristics of copper (Ⅱ) ions from aqueous solution onto humic acid-immobilized surfactant-modified zeolite[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects, 2011,384(1):9-16.
[33]	Kathy L, Godtredsen, Stone A T. Solubilization of manganese of manganese dioxide-bound copper by naturally occurring organic compounds[J]. Environmental Science & Technology, 1994,28:1450-1458.
[34]	Li J, Zhang S, Chen C, et al. Removal of Cu (Ⅱ) and fulvic acid by graphene oxide nanosheets decorated with Fe3O4 nanoparticles[J]. ACS applied materials & interfaces, 2012,4(9):4991-5000.