Modification of Activated Carbon Electrode for Efficient Electrosorption of Co2+， Mn2+ and Ni2+

doi:10.7503/cjcu20220598

Abstract

Abstract:

Two different modified activated carbon（AC） electrode materials were prepared by modification with H₃PO₄ and NaOH using commercial AC as raw material. The surface properties and electrochemical properties of the AC before and after modification were investigated using scanning electron microscope（SEM）， transmission electron microscope（TEM）， Brunauer⁃Emmett⁃Teller（BET） test， Fourier transform infrared spectroscopy（FTIR）， X-ray photoelectron spectroscopy（XPS） and electrochemical analysis. The results showed that the H₃PO₄ modification made the pore distribution of AC denser， and the NaOH modification made the pore structure on the surface of AC more clearer and uniform. The specific surface area of the original AC was increased after modification with H₃PO₄ and NaOH. Moreover， the content of oxygen-containing functional groups of AC was significantly increased by H₃PO₄ and NaOH modifications. The cyclic voltammetry results showed that both modification treatments improved the specific capacitance of the AC electrode. When the scanning rate was 5 mV/s， the specific capacitances of unmodified， H₃PO₄ and NaOH modified AC electrodes were 36.51， 77.25 and 85.19 F/g， respectively. The experimental results of electrosorption experiments demonstrate that both modified AC electrodes had excellent removal effects on Co²⁺， Mn²⁺ and Ni²⁺， and the electrosorption processes were more consistent with the Langmuir model. Under the same experimental conditions， the NaOH-modified electrode had higher removal rates and adsorption capacities for Co²⁺， Mn²⁺ and Ni²⁺. The removal rates could reach 96.84%， 94.37% and 96.90% ， respectively， and the adsorption capacities were 140.8， 111.4 and 108.5 mg/g， respectively. This work indicates the potential application of modified AC electrodes and electrosorption in the efficient remediation of Co²⁺， Mn²⁺ and Ni²⁺.

Key words: Activated carbon, Modification, Electrosorption, Co²⁺, Mn²⁺, Ni²⁺

CLC Number:

O646

TrendMD:

CHEN Jiaqi, CHENG Wanting, WEN Qiuhui, HAN Jingru, MA Fuqiu, YAN Yongde, XUE Yun. Modification of Activated Carbon Electrode for Efficient Electrosorption of Co²⁺， Mn²⁺ and Ni²⁺[J]. Chem. J. Chinese Universities, 2023, 44(4): 20220598.

Figures/Tables 11

References 26

1	Zhang T. K.， Li M. R.， Yin W. P.， Wang Y. R.， Cao S. D.， Gao L. G.， Wang J.， Wang W. Z.， Zheng Y. H.， Bai Y. S.， Blue Book of Nuclear Energy： the Report on the Development of China’s Nuclear Energy， Social Sciences Academic Press（2021）， Beijing， 2021， 1—19
	张廷克，李闽榕，尹卫平，王毅韧，曹述栋，高立刚，王俊，王文宗，郑玉辉，白云生. 核能发展蓝皮书：中国核能发展报告（2021）. 北京：社会科学文献出版社， 2021， 1—19
2	Zhang X. Y.， Liu Y.， Environ Sci⁃Nano， 2020， 7（4）， 1008—1040
3	Zhang M. D.， Study on Development and Application of Novel Adsorbents for Decontamination of Radioactive Strontium and Cobalt from Aqueous Solutions， Tianjin University， Tianjin， 2020
	张铭栋. 用于水中放射性锶、钴核素去除的新型吸附剂开发及应用研究，天津：天津大学， 2020
4	Tang Q. F.， Synthesis of Polyacrylamide Composite and Treatment of Radioactive Wastewater， Chengdu University of Technology， Chengdu， 2020
	唐清枫. 聚丙烯酰胺复合材料合成及放射性废水处理，成都：成都理工大学， 2020
5	Kalfa A.， Shapira B.， Shopin A.， Cohen I.， Avraham E.， Aurbach D.， Chemosphere， 2020， 241， 125003
6	Xing W. L.， Liang J.， Tang， W. W.， He D.， Yan M.， Wang X. X.， Luo Y.， Tang N.， Huang M.， Desalination， 2020， 482， 114390
7	Wang X. W.， Jiang F. T.， Suo Q. L.， Fang Y. Z.， Lu Y.， Chem. J. Chinese Universities， 2012， 33（2）， 321—326
	王喜文，姜芳婷，索全伶，方玉珠，路勇. 高等学校化学学报， 2012， 33（2）， 321—326
8	Chen R.， Hu X. E.， Prog. Chem.， 2006， 18（1）， 80—86
	陈榕，胡熙恩. 化学进展， 2006， 18（1）， 80—86
9	Huang Z. H.， Yang Z. Y.， Kang F. Y.， Inagaki M.， J. Mater. Chem. A， 2017， 5（2）， 470—496
10	Shen W. Z.， Li Z. J.， Liu Y. H.， Recent Pat. Chem. Eng.， 2008， 1， 27
11	Sufiani O.， Tanaka H.， Teshima K.， Machunda R. L.， Jande Y. A. C.， Sep. Purif. Techno.， 2020， 247， 116998
12	Islam M. A.， Ahmed M. J.， Khanday W. A.， Asif M.， Hameed B. H.， J. Environ. Manage.， 2017， 203， 237
13	Hao H. L.， Meng F. Y.， Li R. Y.， Li Y. Q.， Jia M. J.， Zhang W. X.， Yuan X. L.， Chem. J. Chinese Universities， 2022， 43（6）， 226—236
	郝宏蕾，孟繁雨，李若钰，李迎秋，贾明君，张文祥，袁晓玲. 高等学校化学学报， 2022， 43（6）， 226—236
14	Shim J. W.， Park S. J.， Ryu S. K.， Carbon， 2001， 39（11）， 1635—1642
15	Zhao J. Y.， Wang C. B.， Wang C. Y.， Zhang K.， Cong B.， Yang L.， Zhao X. G.， Chen C. H.， Chem. J. Chinese Universities， 2022， 43（4）， 195—204
	赵君禹，王春博，王成杨，张克，丛冰，杨岚，赵晓刚，陈春海. 高等学校化学学报， 2022， 43（4）， 195—204
16	Chen H. F.， Study of Adsorption Removal of Heavy Metals and Cationic Dye from Water by Dopamine Cyclodextrin Polymers and Its Antibacterial Properties， East China University of Science and Technology， Shanghai， 2020
	陈华锋. 多巴胺环糊精聚合物吸附去除水中重金属、阳离子染料及其抗菌性能研究，上海：华东理工大学， 2020
17	Chen Y.， Zhu Y. C.， Wang Z. C.， Li Y.， Wang L. L.， Ding L. L.， Gao X. Y.， Ma Y. J.， Guo Y. P.， Adv. Colloid Interface Sci.， 2011， 163（1）， 39—52
18	Hadoun H.， Sadaoui Z.， Souami N.， Sahel D.， Toumert I.， Appl. Surf. Sci.， 2013， 280， 1—7
19	Niu R.， Li H. B.， Ma Y. L.， He L. J.， Li J.， Electrochim. Acta， 2015， 176， 755—762
20	You F. T.， Yu G. W.， Xing Z. J.， Li J.， Xie S. Y.， Li C. N.， Wang G.， Ren H. Y.， Wang Y.， Appl. Surf. Sci.， 2019， 471， 633—644
21	Chang L.， Hu Y. H.， J. Phys. Chem. Solids， 2018， 116， 347—352
22	Chen C. Y.， Yu F.， Zhou H. M.， Chen J. H.， Ma J.， Chem. J. Chinese Universities， 2015， 36（12）， 2516—2522
	陈春阳，于飞，周慧明，陈君红，马杰. 高等学校化学学报， 2015， 36（12）， 2516—2522
23	Kan K.， Wang Y.， Fu D.， Zheng M. M.， Zhang X. C.， J. Mater. Eng.， 2022， 50（2）， 94—102
	阚侃，王珏，付东，郑明明，张晓臣. 材料工程， 2022， 50（2）， 94—102
24	Qian Y. X.， Yuan Y. H.， Wang H. L.， Liu H.， Zhang J. X.， Shi S.， Guo Z. H.， Wang N.， J. Mater. Chem. A， 2018， 6， 24676—24685
25	Liu X. J.， Wu J. L.， Wang J. L.， Sci. Total Environ.， 2019， 697， 134144
26	Pan M.， Cui C.， Tang W. W.， Guo Z. R.， Zhang D. X.， Xu X. Y.， Li J. Y.， Sep. Purif. Techno.， 2022， 281， 119843

Sample	Surface area/（m²·g^-1）	Avg. pore diameter/nm	Avg. pore volume/（cm³·g^-1）
AC	923.248	2.127	0.128
H₃PO₄⁃AC	984.120	2.118	0.136
NaOH⁃AC	1091.850	2.129	0.177

Sample	Surface area/（m²·g^-1）	Avg. pore diameter/nm	Avg. pore volume/（cm³·g^-1）
AC	923.248	2.127	0.128
H₃PO₄⁃AC	984.120	2.118	0.136
NaOH⁃AC	1091.850	2.129	0.177

Scanning rate/(mV·s^-1)	Specific capacitance/（F·g^-1）
Scanning rate/(mV·s^-1)	AC	H₃PO₄⁃AC	NaOH⁃AC
100	17.03	31.32	25.32
50	23.47	50.36	43.67
20	30.00	63.18	65.80
10	31.71	68.76	70.52
5	36.51	77.25	85.19

Scanning rate/(mV·s^-1)	Specific capacitance/（F·g^-1）
Scanning rate/(mV·s^-1)	AC	H₃PO₄⁃AC	NaOH⁃AC
100	17.03	31.32	25.32
50	23.47	50.36	43.67
20	30.00	63.18	65.80
10	31.71	68.76	70.52
5	36.51	77.25	85.19

Species	Electrosorption capacity/（mg·g^-1）
Species	Co²⁺	Mn²⁺	Ni²⁺
H₃PO₄⁃AC	135.0	109.8	105.6
NaOH⁃AC	140.8	111.4	108.5

Modification of Activated Carbon Electrode for Efficient Electrosorption of Co²⁺， Mn²⁺ and Ni²⁺

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 11

References 26

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	TANG Xiaomeng, YUAN Bifeng, FENG Yuqi. Functions of Plant RNA Modifications and Their Analytical Methods [J]. Chem. J. Chinese Universities, 2023, 44(3): 20220265.
[2]	FANG Xin, ZHAO Ruiqi, MO Jing, WANG Yafen, WENG Xiaocheng. Sequencing Methods for Detection of Nucleic Acid Epigenetic Modifications [J]. Chem. J. Chinese Universities, 2023, 44(3): 20220342.
[3]	HE Yinming, KONG Sudong, LIN Jianguo, XIE Minhao, CHENG Liang. Research Advances of Detection Approaches Towards N⁴-Acetylcytidine（ac⁴C） RNA [J]. Chem. J. Chinese Universities, 2023, 44(3): 20220319.
[4]	ZHANG Qingyi, CAO Jie, SHU Xiao, LIU Jianzhao. Effects of Exogenous N⁶-methyladenosine Incorporation on the Expression of Cellular mRNA Transcripts [J]. Chem. J. Chinese Universities, 2023, 44(3): 20220173.
[5]	HUAN Xinyu, LAI Ganqiang, HUANG Yue, YANG Caiguang. Research Progress on Chemical Intervention of N⁶-Methyladenosine Modification [J]. Chem. J. Chinese Universities, 2023, 44(3): 20220340.
[6]	CHEN Jialu, HUANG Shuo. Applications of Nanopore Sequencing Technology in the Detection of Nucleic Acid Modifications [J]. Chem. J. Chinese Universities, 2023, 44(3): 20220333.
[7]	ZHANG Kaisong, WANG Shaoru, ZHANG Yutong, TIAN Tian. Study of Epigenetic Modifications of Nucleic Acids Based on Supramolecular Chemistry [J]. Chem. J. Chinese Universities, 2023, 44(3): 20220335.
[8]	HE Yuting, NIU Huibin, ZHANG Zhaonian, ZHANG Jing, FU Guirong, CHEN Chuncheng, HUANG Yingping, FANG Yanfen. Modification Mechanism of Mannitol for Preparation of Highly Active Nano-zerovalent Iron [J]. Chem. J. Chinese Universities, 2023, 44(2): 20220470.
[9]	YAN Zhixuan, MA Ji, QU Jinlei, LIU Li, SUN Chong, LIU Jiwen, LIU Guangye, SUN Lishui, HE Lixia. Synthesis and Application of Modified Low Molecular Weight Polyisoprene [J]. Chem. J. Chinese Universities, 2022, 43(6): 20220066.
[10]	ZHAO Sheng, HUO Zhipeng, ZHONG Guoqiang, ZHANG Hong, HU Liqun. Preparation of Modified Gadolinium/Boron/Polyethylene Nanocomposite and Its Radiation Shielding Performance for Neutron and Gamma-ray [J]. Chem. J. Chinese Universities, 2022, 43(6): 20220039.
[11]	HU Huimin, CUI Jing, LIU Dandan, SONG Jiaxin, ZHANG Ning, FAN Xiaoqiang, ZHAO Zhen, KONG Lian, XIAO Xia, XIE Zean. Influence of Different Transition Metal Decoration on the Propane Dehydrogenation Performance over Pt/M-DMSN Catalysts [J]. Chem. J. Chinese Universities, 2022, 43(4): 20210815.
[12]	MENG Xianglong, YANG Ge, GUO Hailing, LIU Chenguang, CHAI Yongming, WANG Chunzheng, GUO Yongmei. Synthesis of Nano-zeolite and Its Adsorption Performance for Hydrogen Sulfide [J]. Chem. J. Chinese Universities, 2022, 43(3): 20210687.
[13]	JIA Hongjun, ZHANG Jiatao, MA Zhuoli, WANG Heng, YANG Xinyu, YANG Jiazhi. Preparation of PTFE/PAA/Nafion Composite Membrane by Aqueous Polymerization of Acrylic Acid and Its Properties [J]. Chem. J. Chinese Universities, 2022, 43(11): 20220350.
[14]	LI Meiyan, CHEN Zijuan, WANG Shuhua, CHEN Chao. Zr-MOF Hollow Nanospheres Supported Ionic Liquid for CO₂ Cycloaddition Reaction [J]. Chem. J. Chinese Universities, 2021, 42(8): 2474.
[15]	BAI Jingqi, BAI Shan, REN Lixia, ZHU Kongying, ZHAO Yunhui, LI Xiaohui, YUAN Xiaoyan. Trehalose-modified Poly（vinyl alcohol） and Their Antifogging/Antifrosting Coatings [J]. Chem. J. Chinese Universities, 2021, 42(8): 2683.