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Journal of Advanced Ceramics 2021, 10(2): 247-257 https://doi.org/10.1007/s40145-020-0435-0
Research Article | Open Access | Issue | Published: 01 March 2021

Hydrous cerium oxides coated glass fiber for efficient and long-lasting arsenic removal from drinking water

Show Author's Information Ronghui LIa Weiyi YANGb Shuang GAOb Jianku SHANGc Qi LIb( )
School of Gemology and Material Technology, Hebei GEO University, Shijiazhuang 050031, China
Key Laboratory of Advanced Technologies of Materials (Ministry of Education), School of Materials Science and Engineering, Southwest Jiaotong University, Chengdu 610031, China
Shenyang National Laboratory for Materials Science, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China
Keywords:
hydrous cerium oxide (HCO), glass fiber cloth (GFC), column test, adsorption kinetics, adsorption mechanism
Cite this article:
LI R, YANG W, GAO S, et al. Hydrous cerium oxides coated glass fiber for efficient and long-lasting arsenic removal from drinking water. Journal of Advanced Ceramics, 2021, 10(2): 247-257. https://doi.org/10.1007/s40145-020-0435-0
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Abstract Full text Electronic supplementary material About this article

A novel arsenic adsorbent with hydrous cerium oxides coated on glass fiber cloth (HCO/GFC) was synthesized. The HCO/GFC adsorbents were rolled into a cartridge for arsenic removal test. Due to the large pores between the glass fibers, the arsenic polluted water can flow through easily. The arsenic removal performance was evaluated by testing the equilibrium adsorption isotherm, adsorption kinetics, and packed-bed operation. The pH effects on arsenic removal were conducted. The test results show that HCO/GFC filter has high As(V) and As(III) removal capacity even at low equilibrium concentration. The more toxic As(III) in water can be easily removed within a wide range of solution pH without pre-treatment. Arsenic contaminated ground-water from Yangzong Lake (China) was used in the column test. At typical breakthrough conditions (the empty bed contact time, EBCT = 2 min), arsenic researched breakthrough at over 24,000 bed volumes (World Health Organization (WHO) suggested that the maximum contaminant level (MCL) for arsenic in drinking water is 10 mg/L). The Ce content in the treated water was lower than 5 ppb during the column test, which showed that cerium did not leach from the HCO/GFC material into the treated water. The relationship between dosage of adsorbents and the adsorption kinetic model was also clarified, which suggested that the pseudo second order model could fit the kinetic experimental data better when the adsorbent loading was relatively low, and the pseudo first order model could fit the kinetic experimental data better when the adsorbent loading amount was relatively high.


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About this article

Hydrous cerium oxides coated glass fiber for efficient and long-lasting arsenic removal from drinking water

Show Author's information Ronghui LIaWeiyi YANGbShuang GAObJianku SHANGcQi LIb( )
School of Gemology and Material Technology, Hebei GEO University, Shijiazhuang 050031, China
Key Laboratory of Advanced Technologies of Materials (Ministry of Education), School of Materials Science and Engineering, Southwest Jiaotong University, Chengdu 610031, China
Shenyang National Laboratory for Materials Science, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China

Abstract

A novel arsenic adsorbent with hydrous cerium oxides coated on glass fiber cloth (HCO/GFC) was synthesized. The HCO/GFC adsorbents were rolled into a cartridge for arsenic removal test. Due to the large pores between the glass fibers, the arsenic polluted water can flow through easily. The arsenic removal performance was evaluated by testing the equilibrium adsorption isotherm, adsorption kinetics, and packed-bed operation. The pH effects on arsenic removal were conducted. The test results show that HCO/GFC filter has high As(V) and As(III) removal capacity even at low equilibrium concentration. The more toxic As(III) in water can be easily removed within a wide range of solution pH without pre-treatment. Arsenic contaminated ground-water from Yangzong Lake (China) was used in the column test. At typical breakthrough conditions (the empty bed contact time, EBCT = 2 min), arsenic researched breakthrough at over 24,000 bed volumes (World Health Organization (WHO) suggested that the maximum contaminant level (MCL) for arsenic in drinking water is 10 mg/L). The Ce content in the treated water was lower than 5 ppb during the column test, which showed that cerium did not leach from the HCO/GFC material into the treated water. The relationship between dosage of adsorbents and the adsorption kinetic model was also clarified, which suggested that the pseudo second order model could fit the kinetic experimental data better when the adsorbent loading was relatively low, and the pseudo first order model could fit the kinetic experimental data better when the adsorbent loading amount was relatively high.

Keywords: hydrous cerium oxide (HCO), glass fiber cloth (GFC), column test, adsorption kinetics, adsorption mechanism

References(35)

[1]
JR Huling, SG Huling, R Ludwig. Enhanced adsorption of arsenic through the oxidative treatment of reduced aquifer solids. Water Res 2017, 123: 183-191.
DOI Google Scholar
[2]
World Health Organization. Guidelines for Drinking-water Quality. 3rd edn. Geneva: WHO Press, 2008: 306.
[3]
SV Jadhav, E Bringas, GD Yadav, et al. Arsenic and fluoride contaminated groundwaters: A review of current technologies for contaminants removal. J Environ Manag 2015, 162: 306-325.
DOI Google Scholar
[4]
Y Kim, C Kim, I Choi, et al. Arsenic removal using mesoporous alumina prepared via a templating method. Environ Sci Technol 2004, 38: 924-931.
DOI Google Scholar
[5]
ZC Xu, Q Li, SA Gao, et al. As(III) removal by hydrous titanium dioxide prepared from one-step hydrolysis of aqueous TiCl(4) solution. Water Res 2010, 44: 5713-5721.
DOI Google Scholar
[6]
S Lin, DN Lu, Z Liu. Removal of arsenic contaminants with magnetic γ-Fe2O3 nanoparticles. Chem Eng J 2012, 211-212: 46-52.
DOI Google Scholar
[7]
TY Sun, ZW Zhao, ZJ Liang, et al. Efficient As(III) removal by magnetic CuO-Fe3O4 nanoparticles through photo-oxidation and adsorption under light irradiation. J Colloid Interface Sci 2017, 495: 168-177.
DOI Google Scholar
[8]
KJ Reddy, KJ McDonald, H King. A novel arsenic removal process for water using cupric oxide nanoparticles. J Colloid Interface Sci 2013, 397: 96-102.
DOI Google Scholar
[9]
H Cui, Y Su, Q Li, et al. Exceptional arsenic (III, V) removal performance of highly porous, nanostructured ZrO2 spheres for fixed bed reactors and the full-scale system modeling. Water Res 2013, 47: 6258-6268.
DOI Google Scholar
[10]
S Lata, SR Samadder. Removal of arsenic from water using nano adsorbents and challenges: A review. J Environ Manag 2016, 166: 387-406.
DOI Google Scholar
[11]
L Zhang, YH Qin, BZ Chen, et al. Catalytic reduction of SO2 by CO over CeO2-TiO2 mixed oxides. Trans Nonferrous Met Soc China 2016, 26: 2960-2965.
DOI Google Scholar
[12]
P Li, XY Chen, YD Li, et al. A review on oxygen storage capacity of CeO2-based materials: Influence factors, measurement techniques, and applications in reactions related to catalytic automotive emissions control. Catal Today 2019, 327: 90-115.
DOI Google Scholar
[13]
K Ackland, JMD Coey. Room temperature magnetism in CeO2—A review. Phys Rep 2018, 746: 1-39.
DOI Google Scholar
[14]
KD Hristovski, PK Westerhoff, JC Crittenden, et al. Arsenate removal by nanostructured ZrO2 spheres. Environ Sci Technol 2008, 42: 3786-3790.
DOI Google Scholar
[15]
AM Raichur, M Jyoti Basu. Adsorption of fluoride onto mixed rare earth oxides. Sep Purif Technol 2001, 24: 121-127.
DOI Google Scholar
[16]
HY Xiao, ZH Ai, LZ Zhang. Non aqueous sol-gel synthesized hierarchical CeO2 nanocrystal microspheres as novel adsorbents for wastewater treatment. J Phys Chem C 2009, 113: 16625-16630.
DOI Google Scholar
[17]
MJ Haron, F Ab Rahim, AH Abdullah, et al. Sorption removal of arsenic by cerium-exchanged zeolite P. Mater Sci Eng: B 2008, 149: 204-208.
DOI Google Scholar
[18]
XJ Peng, ZK Luan, J Ding, et al. Ceria nanoparticles supported on carbon nanotubes for the removal of arsenate from water. Mater Lett 2005, 59: 399-403.
DOI Google Scholar
[19]
WH Xu, J Wang, L Wang, et al. Enhanced arsenic removal from water by hierarchically porous CeO2-ZrO2 nanospheres: Role of surface- and structure-dependent properties. J Hazard Mater 2013, 260: 498-507.
DOI Google Scholar
[20]
RH Li, Q Li, SA Gao, et al. Exceptional arsenic adsorption performance of hydrous cerium oxide nanoparticles: Part A. Adsorption capacity and mechanism. Chem Eng J 2012, 185-186: 127-135.
DOI Google Scholar
[21]
TM Suzuki, JO Bomani, H Matsunaga, et al. Preparation of porous resin loaded with crystalline hydrous zirconium oxide and its application to the removal of arsenic. React Funct Polym 2000, 43: 165-172.
DOI Google Scholar
[22]
WZ Sun, Q Li, SA Gao, et al. Exceptional arsenic adsorption performance of hydrous cerium oxide nanoparticles: Part B. Integration with silica monoliths and dynamic treatment. Chem Eng J 2012, 185-186: 136-143.
DOI Google Scholar
[23]
JH Chen, PS Liu, W Cheng. PBA-loaded albite-base ceramic foam in application to adsorb harmful ions of Cd, Cs and As(V) in water. Multidiscip Model Mater Struct 2019, 15: 659-672.
DOI Google Scholar
[24]
PS Liu, G Cui, YJ Guo, et al. A novel sort of porous ceramic foam ball with modified surface for arsenic removal from aqueous solution. J Iron Steel Res Int 2017, 24: 661-668.
DOI Google Scholar
[25]
S Padungthon, JZ Li, M German, et al. Hybrid anion exchanger with dispersed zirconium oxide nanoparticles: A durable and reusable fluoride-selective sorbent. Environ Eng Sci 2014, 31: 360-372.
DOI Google Scholar
[26]
PL Smedley, DG Kinniburgh. A review of the source, behaviour and distribution of arsenic in natural waters. Appl Geochem 2002, 17: 517-568.
DOI Google Scholar
[27]
K Banerjee, GL Amy, M Prevost, et al. Kinetic and thermodynamic aspects of adsorption of arsenic onto granular ferric hydroxide (GFH). Water Res 2008, 42: 3371-3378.
DOI Google Scholar
[28]
SB Deng, G Yu, SH Xie, et al. Enhanced adsorption of arsenate on the aminated fibers: Sorption behavior and uptake mechanism. Langmuir 2008, 24: 10961-10967.
DOI Google Scholar
[29]
P Suresh Kumar, L Korving, KJ Keesman, et al. Effect of pore size distribution and particle size of porous metal oxides on phosphate adsorption capacity and kinetics. Chem Eng J 2019, 358: 160-169.
DOI Google Scholar
[30]
YS Ho, G McKay. The sorption of lead(II) ions on peat. Water Res 1999, 33: 578-584.
DOI Google Scholar
[31]
Y Ho, G McKay. The kinetics of sorption of divalent metal ions onto sphagnum moss peat. Water Res 2000, 34: 735-742.
DOI Google Scholar
[32]
YS Ho, G McKay. Pseudo-second order model for sorption processes. Process Biochem 1999, 34: 451-465.
DOI Google Scholar
[33]
CA Martinson, KJ Reddy. Adsorption of arsenic (III) and arsenic (V) by cupric oxide nanoparticles. J Colloid Interface Sci 2009, 336: 406-411.
DOI Google Scholar
[34]
Y Zhang, M Yang, XM Dou, et al. Arsenate adsorption on an Fe-Ce bimetal oxide adsorbent: Role of surface properties. Environ Sci Technol 2005, 39: 7246-7253.
DOI Google Scholar
[35]
S Goldberg, CT Johnston. Mechanisms of arsenic adsorption on amorphous oxides evaluated using macroscopic measurements, vibrational spectroscopy, and surface complexation modeling. J Colloid Interface Sci 2001, 234: 204-216.
DOI Google Scholar
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Publication history

Received: 17 July 2020
Revised: 29 October 2020
Accepted: 30 October 2020
Published: 01 March 2021
Issue date: April 2021

Copyright

© The Author(s) 2020

Acknowledgements

This study was supported by the National Natural Science Foundation of China (Grant Nos. 51672283 and 51902271), the Fundamental Research Funds for the Central Universities (Grant Nos. A1920502051907-15, 2682020CX07, and 2682020CX08), Sichuan Science and Technology Program (Grant Nos. 2020YJ0259 and 2020YJ0072), Doctoral Research Start-up Fund of Hebei GEO University (Grant No. BQ2019003), Joint fund between Shenyang National Laboratory for Materials Science and State Key Laboratory of Advanced Processing and Recycling of Nonferrous Metals (Grant No. 18LHPY009), and Liaoning Baiqianwan Talents Program.

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