电化学驱动水钠锰矿高效吸附去除混合重金属离子

刘立虎; 樊萍; 孙学成; 蔡建波; 彭启川; 谭文峰; 邱国红

doi:10.7524/j.issn.0254-6108.2020092901

华中农业大学资源与环境学院，土壤环境与污染修复湖北省重点实验室，农业农村部长江中下游耕地保育重点实验室，武汉，430070

黄冈市农业环境保护站，黄冈，438000

通讯作者: Tel：13554035006，E-mail: qiugh@mail.hzau.edu.cn

基金项目:

国家重点研发计划（2018YFD0800304），国家自然科学基金（42007127）和国家博士后创新人才支持计划（BX20200144）资助.

High-efficiency adsorption removal for multiple heavy metal ions using birnessite under electrochemical drive

Key Laboratory of Arable Land Conservation (Middle and Lower Reaches of Yangtze River) , Ministry of Agriculture, College of Resources and Environment, Hubei Key Laboratory of Soil Environment and Pollution Remediation, Huazhong Agricultural University, Wuhan, 430070, China

Huanggang Agricultural Environmental Protection Station, Huanggang 438000, China

Corresponding author: QIU Guohong, qiugh@mail.hzau.edu.cn

Fund Project: National Key Research and Development Program of China (2018YFD0800304), National Natural Science Foundation of China (42007127) and National Postdoctoral Program for Innovative Talents (BX20200144).

摘要: 锰氧化物被广泛用作重金属离子吸附剂，电化学调控其氧化还原反应程度可提高重金属吸附容量。然而，多种重金属离子共存时的电化学吸附过程及相互影响机理尚不清楚。本工作采用多周恒流充放电方式研究了水钠锰矿对Cd²⁺、Zn²⁺、Pb²⁺与Ni²⁺单独及共存时的电化学吸附性能及机理，同时考察了氧化还原程度对吸附性能的影响。结果表明，重金属离子的电化学吸附容量明显高于断路条件下的物理化学吸附容量。在0.5 mmol·L⁻¹单一及多种重金属离子混合溶液中，水钠锰矿电化学吸附容量大小顺序均为Pb²⁺＞Cd²⁺＞Zn²⁺＞Ni²⁺。在单一重金属离子溶液中，Cd²⁺、Zn²⁺、Pb²⁺和Ni²⁺的去除率分别为41.8%、37.2%、85.6%与31.3%。多重金属离子共存时，Pb²⁺的去除率受其他重金属离子影响较小。Pb²⁺优先占据水钠锰矿上吸附位点阻碍了Cd²⁺、Zn²⁺与Ni²⁺的吸附，导致相应去除率分别降至19.9%、11.6%和5.4%。共吸附过程中，Cd²⁺对Zn²⁺与Ni²⁺有抑制作用，Zn²⁺与Ni²⁺互相抑制且Zn²⁺对Ni²⁺抑制作用较强。随着水钠锰矿氧化还原程度加剧，Pb²⁺去除率明显增加，Cd²⁺、Zn²⁺和Ni²⁺的去除率变化不大。该研究可为锰氧化物用于电化学吸附处理重金属污染废水提供基础数据和参考。

Abstract: Manganese oxides are widely used as adsorbents for heavy metal ions, and their adsorption performance can be enhanced by the electrochemical control of the redox degree. However, the electrochemical adsorption process and interaction mechanism are still enigmatic at the co-existence of multiple heavy metal ions. In this work, the individual and competitive electrochemical adsorption performance and mechanism of birnessite for Cd²⁺, Zn²⁺, Pb²⁺ and Ni²⁺ were investigated by multi-cycle galvanostatic charge–discharge, and the effect of redox degree on the electrochemical adsorption performance was also studied. The results indicated that the electrochemical adsorption capacity was much higher than the physicochemical adsorption capacity of birnessite for these heavy metal ions. In the solutions containing 0.5 mmol·L⁻¹ individual or mixed heavy metal ions, the electrochemical adsorption capacity follows the order of Pb²⁺ > Cd²⁺ > Zn²⁺ > Ni²⁺. The individual electrochemical removal efficiency was 41.8%, 37.2%, 85.6% and 31.3% for Cd²⁺, Zn²⁺, Pb²⁺ and Ni²⁺, respectively. In the solutions containing mixed heavy metal ions, the electrochemical removal efficiency of Pb²⁺ seemed not to be remarkably affected by the presence of other heavy mental ions. The preferential occupation of adsorption sites by Pb²⁺ obviously impended the electrochemical adsorption of Cd²⁺, Zn²⁺ and Ni²⁺ on birnessite, leading to decreases of their removal efficiency to 19.9%, 11.6% and 5.4%, respectively. The presence of Cd²⁺ inhibited the adsorption of Zn²⁺ and Ni²⁺, and the adsorption of Zn²⁺ and Ni²⁺ inhibited each other, with Zn²⁺ exhibiting a stronger inhibitory effect on Ni²⁺. With increasing redox degree of birnessite, the removal efficiency of Pb²⁺ significantly increased, while that of Cd²⁺, Zn²⁺ and Ni²⁺ showed little change. This study provides basic data and reference for the application of manganese oxides in electrochemical adsorption of heavy metal contaminated wastewaters.

Key words:

电化学驱动水钠锰矿高效吸附去除混合重金属离子

通讯作者: Tel：13554035006，E-mail: qiugh@mail.hzau.edu.cn

1. 华中农业大学资源与环境学院，土壤环境与污染修复湖北省重点实验室，农业农村部长江中下游耕地保育重点实验室，武汉，430070

2. 黄冈市农业环境保护站，黄冈，438000

收稿日期: 2020-09-29

录用日期: 2022-01-13

网络出版日期: 2022-02-25

基金项目:

国家重点研发计划（2018YFD0800304），国家自然科学基金（42007127）和国家博士后创新人才支持计划（BX20200144）资助.

关键词:

High-efficiency adsorption removal for multiple heavy metal ions using birnessite under electrochemical drive

Corresponding author: QIU Guohong, qiugh@mail.hzau.edu.cn

1. Key Laboratory of Arable Land Conservation (Middle and Lower Reaches of Yangtze River) , Ministry of Agriculture, College of Resources and Environment, Hubei Key Laboratory of Soil Environment and Pollution Remediation, Huazhong Agricultural University, Wuhan, 430070, China

2. Huanggang Agricultural Environmental Protection Station, Huanggang 438000, China

Received Date: 2020-09-29

Accepted Date: 2022-01-13

Available Online: 2022-02-25

Keywords:

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随着采矿、冶金、电镀及电池制造等行业的快速发展，重金属离子已成为污染水体的重要组分^[1]。重金属离子具有生物体内难降解、高毒及致癌等特性严重威胁人类健康与生态环境^[1]。因此，高效去除污染水体中重金属的技术已成全球研究的热点。当前去除与回收水体重金属离子的主要方法有化学共沉淀、离子交换、膜过滤、吸附和电沉积等，而具有低成本、易操作等优势的吸附法应用前景看好^[1-3]。

锰氧化物以其零电荷点低、资源丰富且环境友好等特点被广泛用于吸附去除水体重金属^[4-6]。常见的锰氧化物有水钠锰矿、锰钾矿、钙锰矿和黑锰矿等。不同锰氧化物的零电荷点、微观形貌、比表面积等特性存在差异，相应的重金属吸附容量也不尽相同，如对Zn²⁺、Pb²⁺和Cd²⁺的吸附容量顺序为水钠锰矿>锰钾矿>钙锰矿>黑锰矿^[6]。此外，同一晶体结构类型的锰氧化物化学组成不同，其对重金属离子吸附容量也存在差异，如锰平均氧化度越高的水钠锰矿吸附重金属容量越高^[7]。在pH 7.5的厌氧条件下，Mn²⁺诱导水钠锰矿还原为水锰矿（β-MnOOH）和黑锰矿（Mn₃O₄）等低价锰氧化物的过程可显著提升其对Ni²⁺和Zn²⁺的吸附容量^[8-9]。因此，通过氧化还原反应改变锰氧化物组成及特性可望提高其重金属吸附容量。

水钠锰矿是由共边的MnO₆八面体层与水分子相互交错堆叠而成，独特的结构使其具有较好阳离子交换量、氧化还原特性及重金属吸附容量^[7,10-11]。我们前期工作中发现电化学驱动的氧化还原过程中，水钠锰矿形貌、化学组成及锰平均氧化度等特性的改变显著提高了其重金属离子吸附容量，如在多周循环氧化还原过程中，水钠锰矿对Zn²⁺、Cd²⁺和Cu²⁺的最大电化学吸附容量分别高达530.0、900.7、372.3 mg·g⁻¹，约为等温吸附容量的8—10倍^[12-14]。污染水体中通常含有多种重金属离子，在吸附过程中需考虑它们之间的相互影响。研究表明碱性钙基膨润土吸附多种重金属容量为Pb²⁺>Cu²⁺>Zn²⁺，且重金属间的吸附会相互抑制^[15]。不同重金属在水钠锰矿上吸附作用力的强弱及位点差异也使其吸附容量不同^[7]。在锰氧化物电化学吸附重金属过程中，多种重金属离子吸附容量及其相互作用机制尚不清楚。

本文以水钠锰矿为电极材料，在含有Cd²⁺、Zn²⁺、Pb²⁺与Ni²⁺的溶液体系中，系统考察了恒流充放电控制的电化学氧化还原过程中重金属离子间的相互作用对其在水钠锰矿上电化学吸附容量及机理的影响。

1. 材料与方法（Materials and methods）

1.1. 水钠锰矿的制备

采用浓盐酸还原煮沸的高锰酸钾制备水钠锰矿^[16]。将300 mL浓度为0.667 mol·L⁻¹高锰酸钾溶液搅拌并加热至100 ℃，用恒流泵将45 mL浓度6.0 mol·L⁻¹盐酸溶液以0.7 mL·min⁻¹速率逐滴加入高锰酸钾溶液，滴加完毕后继续反应30 min。将反应获得的悬浊液置于60 ℃恒温烘箱静置12 h后用去离子水清洗至滤液电导小于10 μS·cm⁻¹，再用乙醇洗涤3次后在鼓风烘箱中干燥。获得的水钠锰矿经研磨过100目筛后备用。

1.2. 重金属的电化学去除

电化学去除重金属离子实验在三电极体系中进行，温度为25 ℃。将合成水钠锰矿、导电剂乙炔黑及粘合剂聚偏氟乙烯按质量比75∶15∶10称量。水钠锰矿先与乙炔黑混合研磨30 min后转移至离心管，随后向其中加入聚偏氟乙烯及溶剂N-甲基吡咯烷酮超声混合形成均匀的浆料。将一定质量的浆料涂布于尺寸为3.5 cm×2.5 cm的碳纸上，在40 ℃下真空干燥12 h制得工作电极。工作电极上水钠锰矿的质量约为5.0 mg，相同尺寸的空白碳纸作为对电极，饱和甘汞电极作为（SCE）参比电极。重金属离子的电化学去除实验在深圳市新威尔电子有限公司的CT-3008W-5V1A型电池性能测试系统上以多周循环恒流充放电方式进行，循环周数设定为50周，电流密度和电位窗口（vs. SCE）分别为0.1 A·g⁻¹和0—0.9 V。

分别采用Cd(NO₃)₂、Zn(NO₃)₂、Pb(NO₃)₂以及Ni(NO₃)₂配制含重金属Cd²⁺、Zn²⁺、Pb²⁺与Ni²⁺的溶液，NaNO₃作为背景电解质，浓度为0.1 mol·L⁻¹。采用0.1 mol·L⁻¹ H₂SO₄和NaOH调节重金属溶液初始pH值为5.0，电化学去除过程中重金属溶液体积为30 mL。单独含0.5 mmol·L⁻¹的Cd²⁺、Zn²⁺、Pb²⁺与Ni²⁺溶液用于考察不同重金属离子的电化学吸附容量，而浓度均为0.5 mmol·L⁻¹的Cd²⁺、Zn²⁺、Pb²⁺与Ni²⁺混合溶液用于考察电化学吸附过程中共存重金属离子相互影响。不加电场的断路条件下48 h物理化学吸附实验用于与电化学吸附对比。分别配制0.5 mmol ·L⁻¹的Cd²⁺与Zn²⁺、Cd²⁺与Pb²⁺、Cd²⁺与Ni²⁺、Zn²⁺与Ni²⁺的4种混合溶液用于进一步考察不同重金属离子电化学去除过程中竞争作用。为比较水钠锰矿对不同重金属离子的去除速率，控制其在Cd²⁺、Zn²⁺、Pb²⁺与Ni²⁺的混合溶液中充放电1—65 周。为考察电化学氧化还原程度对重金属离子吸附的影响，在单独和混合重金属离子溶液中分别控制电位窗口为0—0.3 V和0—0.6 V进行50周充放电实验。

1.3. 分析与表征

采用Bruker公司配备铜靶的D8 Advance型X-射线衍射仪（XRD）表征水钠锰矿及电极上产物的晶体结构。采用Hitachi公司的SU8010型场发射扫描电镜（FESEM）观察产物微观形貌。采用Thermo Scientific公司傅里叶变换红外光谱仪（FTIR，Nicolet 8700）分析样品特征官能团。电化学氧化还原反应结束后取出电极并用去离子水冲洗以去除残留溶液。采用Agilent公司原子吸收光谱仪（AAS240FS）测定溶液中重金属离子浓度。采用上海辰华仪器有限公司CHI660E电化学工作站测试水钠锰矿电极在不同重金属溶液中的循环伏安曲线，扫速为0.5 mV·s⁻¹。水钠锰矿的电化学比容量及对重金属的电化学去除能力分别通过公式（1）和（2）计算：

式中，I（A）为放电电流，t（s）为放电时间，m（mg）为电极上水钠锰矿质量，ΔV（V）为电位窗口，Q_e（mg·g⁻¹）为电吸附比容量，C₀（mg·L⁻¹）为体系中重金属离子初始浓度，C_e（mg·L⁻¹）为电化学吸附反应后重金属浓度，V（mL）为溶液体积。

3. 结论（Conclusion）

电化学吸附过程中，多周不完全可逆的氧化还原反应可显著提升水钠锰矿对单一及混合重金属离子Pb²⁺、Cd²⁺、Zn²⁺和Ni²⁺的去除容量。电化学去除率大小顺序为Pb²⁺>Cd²⁺>Zn²⁺>Ni²⁺，与断路条件下水钠锰矿物理化学吸附去除率顺序基本一致。重金属阳离子的水解常数，吸附位点及水合离子半径均可影响其在水钠锰矿上的吸附容量。Pb²⁺优先被水钠锰矿电化学吸附，使Cd²⁺、Zn²⁺、Ni²⁺的去除率降低。Cd²⁺对Zn²⁺和Ni²⁺吸附有抑制作用，而Zn²⁺与Ni²⁺之间互相抑制且Zn²⁺对Ni²⁺抑制作用较强。氧化还原程度影响水钠锰矿的对重金属离子的电化学吸附性能。随着电位窗口增加，氧化还原程度加剧，吸附活性高的Pb²⁺去除率随电位窗口增加而显著提高。

参考文献 (24)

[1]	刘金燕, 刘立华, 薛建荣, 等. 重金属废水吸附处理的研究进展 [J]. 环境化学, 2018, 37(9): 2016-2024. doi: 10.7524/j.issn.0254-6108.2017110105 LIU J Y, LIU L H, XUE J R, et al. Research progress on treatment of heavy metal wastewater by adsorption [J]. Environmental Chemistry, 2018, 37(9): 2016-2024(in Chinese). doi: 10.7524/j.issn.0254-6108.2017110105
[2]	ZHOU G, LUO J, LIU C, et al. A highly efficient polyampholyte hydrogel sorbent based fixed-bed process for heavy metal removal in actual industrial effluent [J]. Water Research, 2016, 89: 151-160. doi: 10.1016/j.watres.2015.11.053
[3]	谢厦, 徐应明, 闫翠侠, 等. 酸碱复合改性海泡石亚结构特征及其对Cd(II)吸附性能 [J]. 环境科学, 2020, 41(1): 293-303. XIE X, XU Y M, YAN C X, et al. Substructure characteristics of combined acid-base modified sepiolite and its adsorption for Cd(II) [J]. Environmental Science, 2020, 41(1): 293-303(in Chinese).
[4]	LIU L H, TAN W F, SUIB S L, et al. Effective zinc adsorption driven by electrochemical redox reactions of birnessite nanosheets generated by solar photochemistry [J]. ACS Sustainable Chemistry & Engineering, 2018, 6(11): 13907-13914.
[5]	马俊平, 赵秋宇, 王晨, 等. 二氧化锰基纳米材料对重金属离子的去除及机理研究进展 [J]. 环境化学, 2020, 39(3): 687-703. doi: 10.7524/j.issn.0254-6108.2019090207 MA J P, ZHAO Q Y, WANG C, et al. Removal of heavy metal ions by manganese dioxide-based nanomaterials and mechanism research: A review [J]. Environmental Chemistry, 2020, 39(3): 687-703(in Chinese). doi: 10.7524/j.issn.0254-6108.2019090207
[6]	FENG X H, ZHAI L M, TAN W F, et al. Adsorption and redox reactions of heavy metals on synthesized Mn oxide minerals [J]. Environmental Pollution, 2007, 147(2): 366-373. doi: 10.1016/j.envpol.2006.05.028
[7]	WANG Y, FENG X H, VILLALOBOS M, et al. Sorption behavior of heavy metals on birnessite: Relationship with its Mn average oxidation state and implications for types of sorption sites [J]. Chemical Geology, 2012, 292/293: 25-34. doi: 10.1016/j.chemgeo.2011.11.001
[8]	LEFKOWITZ J P, ELZINGA, E J. Impacts of aqueous Mn(Ⅱ) on the sorption of Zn(Ⅱ) by hexagonal birnessite [J]. Environmental Science & Technology, 2015, 49(8): 4886-4893.
[9]	LEFKOWITZ J P, ELZINGA E J. Structural alteration of hexagonal birnessite by aqueous Mn(Ⅱ): Impacts on Ni(Ⅱ) sorption [J]. Chemical Geology, 2017, 466: 524-532. doi: 10.1016/j.chemgeo.2017.07.002
[10]	LIU J T, GE X, YE X X, et al. 3D graphene/δ-MnO₂ aerogels for highly efficient and reversible removal of heavy metal ions [J]. Journal of Materials Chemistry A, 2016, 4(5): 1970-1979. doi: 10.1039/C5TA08106H
[11]	费杨, 阎秀兰, 李永华. 铁锰双金属材料在不同pH条件下对土壤As和重金属的稳定化作用[J]. 环境科学, 2018, 39(3)∶1430–1437, 1435–1437. FEI Y, YAN X L, LI Y H, Stabilization effects of Fe-Mn binary oxide on arsenic and heavy metal cocontaminated soils under different pH conditions[J]. Environmental Science, 2018, 39(3): 1430–1433, 1435–1437 (in Chinese).
[12]	LIU L H, LUO Y, TAN W F, et al. Zinc removal from aqueous solution using a deionization pseudocapacitor with a high-performance nanostructured birnessite electrode [J]. Environmental Science:Nano, 2017, 4: 811-823. doi: 10.1039/C6EN00671J
[13]	YANG X, LIU L H, TAN W F, et al. High-performance Cu²⁺ adsorption of birnessite using electrochemically controlled redox reactions [J]. Journal of Hazardous Materials, 2018, 354: 107-115. doi: 10.1016/j.jhazmat.2018.04.069
[14]	PENG Q C, LIU L H, LUO Y, et al. Cadmium removal from aqueous solution by a deionization supercapacitor with a birnessite electrode [J]. ACS Applied Materials & Interfaces, 2016, 8(50): 34405-34413.
[15]	刘坤, 閤明勇, 汤睿, 等. Pb(Ⅱ)、Zn(Ⅱ)、Cu(Ⅱ)在碱性钙基膨润土上的竞争吸附 [J]. 非金属矿, 2019, 42(1): 17-20. doi: 10.3969/j.issn.1000-8098.2019.01.006 LIU K, HE M Y, TANG R, et al. Competitive adsorption of Pb(Ⅱ), Zn(Ⅱ) and Cu(Ⅱ) on alkaline Ca-bentonite [J]. Non-Metallic Mines, 2019, 42(1): 17-20(in Chinese). doi: 10.3969/j.issn.1000-8098.2019.01.006
[16]	MCKENZIE R M. The synthesis of birnessite, cryptomelane, and some other oxides and hydroxides of manganese [J]. Mineralogical Magazine, 1971, 38(296): 493-502. doi: 10.1180/minmag.1971.038.296.12
[17]	ZHAO W, LIU F, FENG X H, et al. Fourier transform infrared spectroscopy study of acid birnessites before and after Pb²⁺ adsorption [J]. Clay Minerals, 2012, 47(2): 191-204. doi: 10.1180/claymin.2012.047.2.04
[18]	LIU L H, QIU G H, SUIB S L, et al. Enhancement of Zn²⁺ and Ni²⁺ removal performance using a deionization pseudocapacitor with nanostructured birnessite and its carbon nanotube composite electrodes [J]. Chemical Engineering Journal, 2017, 328: 464-473. doi: 10.1016/j.cej.2017.07.066
[19]	LIU L H, LUO Y, TAN W F, et al. Facile synthesis of birnessite-type manganese oxide nanoparticles as supercapacitor electrode materials [J]. Journal of Colloid and Interface Science, 2016, 482: 183-192. doi: 10.1016/j.jcis.2016.07.077
[20]	KWON K D, REFSON K, SPOSITO G. Understanding the trends in transition metal sorption by vacancy sites in birnessite [J]. Geochimica et Cosmochimica Acta, 2013, 101: 222-232. doi: 10.1016/j.gca.2012.08.038
[21]	KWON K D, REFSON K, SPOSITO G. Surface complexation of Pb(Ⅱ) by hexagonal birnessite nanoparticles [J]. Geochimica et Cosmochimica Acta, 2010, 74(23): 6731-6740. doi: 10.1016/j.gca.2010.09.002
[22]	KWON K D, REFSON K, SPOSITO G. Zinc surface complexes on birnessite: A density functional theory study [J]. Geochimica et Cosmochimica Acta, 2009, 73(5): 1273-1284. doi: 10.1016/j.gca.2008.11.033
[23]	PEÑA J, KWON K D, REFSON K, et al. Mechanisms of nickel sorption by a bacteriogenic birnessite [J]. Geochimica et Cosmochimica Acta, 2010, 74(11): 3076-3089. doi: 10.1016/j.gca.2010.02.035
[24]	VOLKOV A G, PAULA S, DEAMER D W. Two mechanisms of permeation of small neutral molecules and hydrated ions across phospholipid bilayers [J]. Bioelectrochemistry and Bioenergetics, 1997, 42(2): 153-160. doi: 10.1016/S0302-4598(96)05097-0