Process and mechanism investigation on comprehensive utilization of arsenic-alkali residue

Ao Gong; Xuan-gao Wu; Jin-hui Li; Rui-xiang Wang; Jia-cong Xu; Sheng-hui Wen; Qin Yi; Lei Tian; Zhi-feng Xu

doi:10.1007/s11771-023-5253-4

Journal of Central South University ›› 2023, Vol. 30 ›› Issue (3) : 721 -734. DOI: 10.1007/s11771-023-5253-4

Article

Process and mechanism investigation on comprehensive utilization of arsenic-alkali residue

Ao Gong ¹^,²
, Xuan-gao Wu ¹^,²
, Jin-hui Li ¹^,²
, Rui-xiang Wang ¹^,²
, Jia-cong Xu ¹^,²
, Sheng-hui Wen ¹^,²
, Qin Yi ¹^,²
, Lei Tian ¹^,²^,^h
, Zhi-feng Xu ¹^,³^,^j

Author information +

History +

PDF

Abstract

Arsenic-alkali residue is a solid waste produced by the antimony smelting industry, which can pose a threat to the environment and human health. The common wet treatment process of arsenic-alkali residue has a low recovery of valuable elements, incomplete separation of arsenic and alkali, and also produces arsenic-alkali mixed salt, which cannot realize the completely harmless treatment of arsenic-alkali residue. In order to solve these problems, the oxidative water leaching process was used to treat arsenic-alkali residue, which realized the separation of arsenic and antimony. The leaching efficiencies of arsenic and antimony were 91.79% and 0.62%, respectively. The leaching residue could be returned to the antimony smelting system to recover antimony. Then the arsenic and alkali were directly separated from the arsenic-alkali mixed salt by carbothermal reduction, and 98.3% of arsenic was removed, and the non-toxic metallic arsenic with 99.9% purity was prepared. The alkali could be recovered from the slag after reduction, which solved the problem of harmless and recycling treatment of arsenic-alkali mixed salts. The mechanism of arsenic reduction pathway was studied through thermodynamic, phase, and arsenic valence state analyses.

Keywords

arsenic-alkali residue / resource recovery / separation / carbothermal reduction / metallic arsenic

Cite this article

Download citation ▾

Ao Gong, Xuan-gao Wu, Jin-hui Li, Rui-xiang Wang, Jia-cong Xu, Sheng-hui Wen, Qin Yi, Lei Tian, Zhi-feng Xu. Process and mechanism investigation on comprehensive utilization of arsenic-alkali residue. Journal of Central South University, 2023, 30(3): 721-734 DOI:10.1007/s11771-023-5253-4

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	ZhaoT-congAntimony [M], 1987, Beijing, Metallurgical Industry Press(in Chinese)

[2]	JiangG-h, MinX-b, KeY, et al. . Solidification/stabilization of highly toxic arsenic-alkali residue by MSWI fly ash-based cementitious material containing Friedel’s salt: Efficiency and mechanism [J]. Journal of Hazardous Materials, 2022, 425: 127992

[3]	WangD-y, RepoE, HeF-s, et al. . Dual functional sites strategies toward enhanced heavy metal remediation: Interlayer expanded Mg-Al layered double hydroxide by intercalation with L [J]. Journal of Hazardous Materials, 2022, 439129693

[4]	ChaiF, ZhangR, MinX-b, et al. . Highly efficient removal of arsenic (III/V) from groundwater using nZVI functionalized cellulose nanocrystals fabricated via a bioinspired strategy [J]. Science of the Total Environment, 2022, 842156937

[5]	HeM-c, WangX-q, WuF-c, et al. . Antimony pollution in China [J]. Science of the Total Environment, 2012, 421–42241-50

[6]	GuoX-j, WangK-p, HeM-c, et al. . Antimony smelting process generating solid wastes and dust: Characterization and leaching behaviors [J]. Journal of Environmental Sciences, 2014, 26(7): 1549-1556

[7]	LiJ-s, LiangH-qing. Treatment strategies study on the comprehensive utilization of arsenic-alkali residue in xikuangshan area [J]. Hunan Nonferrous Metals, 2010, 26(5): 53-5576. (in Chinese)

[8]	LongH, HuangX-z, ZhengY-j, et al. . Purification of crude As₂O₃ recovered from antimony smelting arsenic-alkali residue [J]. Process Safety and Environmental Protection, 2020, 139: 201-209

[9]	ChenC-h, LaiM, FangF-zhou. Study on the crack formation mechanism in nano-cutting of gallium arsenide [J]. Applied Surface Science, 2021, 540: 148322

[10]	WangC-l, WangD, YangR-q, et al. . Preparation and electrical properties of wollastonite coated with antimony-doped tin oxide nanoparticles [J]. Powder Technology, 2019, 342397-403

[11]	TangG-w, LiuW-w, QianQ, et al. . Antimony selenide core fibers [J]. Journal of Alloys and Compounds, 2017, 694: 497-501

[12]	LiL, ZhangR-j, LiaoB, et al. . Separation of As from As and Sb contained smoke dust by selective oxidation [J]. The Chinese Journal of Process Engineering, 2014, 14(1): 71-77(in Chinese)

[13]	ZhangN, FangZ-w, LongH, et al. . Stabilization of arsenic from arsenic alkali residue by forming crystalline scorodite [J]. The Chinese Journal of Nonferrous Metals, 2020, 30(1): 203-213(in Chinese)

[14]	TianJ, SunW, ZhangX-f, et al. . Comprehensive utilization and safe disposal of hazardous arsenic-alkali slag by the combination of beneficiation and metallurgy [J]. Journal of Cleaner Production, 2021, 295: 126381

[15]	ZhangW-j, CheJ-y, XiaL, et al. . Efficient removal and recovery of arsenic from copper smelting flue dust by a roasting method: Process optimization, phase transformation and mechanism investigation [J]. Journal of Hazardous Materials, 2021, 412125232

[16]	XueJ-r, LongD-p, ZhongH, et al. . Comprehensive recovery of arsenic and antimony from arsenic-rich copper smelter dust [J]. Journal of Hazardous Materials, 2021, 413125365

[17]	ZhangY-h, FengX-y, QianL, et al. . Separation of arsenic and extraction of zinc and copper from high-arsenic copper smelting dusts by alkali leaching followed by sulfuric acid leaching [J]. Journal of Environmental Chemical Engineering, 2021, 9(5): 105997

[18]	WangX, DingJ-q, WangL-l, et al. . Stabilization treatment of arsenic-alkali residue (AAR): Effect of the coexisting soluble carbonate on arsenic stabilization [J]. Environment International, 2020, 135105406

[19]	CoussyS, PaktuncD, RoseJ, et al. . Arsenic speciation in cemented paste backfills and synthetic calcium-silicate-hydrates [J]. Minerals Engineering, 2012, 3951-61

[20]	LiangY-j, MinX-b, ChaiL-y, et al. . Stabilization of arsenic sludge with mechanochemically modified zero valent iron [J]. Chemosphere, 2017, 1681142-1151

[21]	JiangG-h, MinX-b, KeY, et al. . Solidification/stabilization of highly toxic arsenic-alkali residue by MSWI fly ash-based cementitious material containing Friedel’s salt: Efficiency and mechanism [J]. Journal of Hazardous Materials, 2022, 425: 127992

[22]	TianJ, WangY-f, ZhangX-f, et al. . A novel scheme for safe disposal and resource utilization of arsenic-alkali slag [J]. Process Safety and Environmental Protection, 2021, 156429-437

[23]	SuR, MaX, LinJ-r, et al. . An alternative method for the treatment of metallurgical arsenic-alkali residue and recovery of high-purity sodium bicarbonate [J]. Hydrometallurgy, 2021, 202: 105590

[24]	LongH, ZhengY-j, PengY-l, et al. . Separation and recovery of arsenic and alkali products during the treatment of antimony smelting residues [J]. Minerals Engineering, 2020, 153106379

[25]	LongH, ZhengY-j, PengY-l, et al. . Recovery of alkali, selenium and arsenic from antimony smelting arsenic-alkali residue [J]. Journal of Cleaner Production, 2020, 251119673

[26]	LeiJ, PengB, LiangY-j, et al. . Effects of anions on calcium arsenate crystalline structure and arsenic stability [J]. Hydrometallurgy, 2018, 177123-131

[27]	ZhaoF-p, ChenS-x, XiangH-r, et al. . Selectively capacitive recovery of rare earth elements from aqueous solution onto Lewis base sites of pyrrolic-N doped activated carbon electrodes [J]. Carbon, 2022, 197: 282-291

[28]	YangY-d, ZhangZ-t, LiY-h, et al. . The catalytic aerial oxidation of As(III) in alkaline solution by Mn-loaded diatomite [J]. Journal of Environmental Management, 2022, 317: 115380

[29]	TianL, YuX-q, XuJ-c, et al. . Preparation and study of tungsten carbide catalyst synergistically codoped with Fe and nitrogen for oxygen reduction reaction [J]. Journal of Materials Research and Technology, 2021, 157100-7110

[30]	WangS-l, MulliganC N. Speciation and surface structure of inorganic arsenic in solid phases: A review [J]. Environment International, 2008, 34(6): 867-879

[31]	OuvrardS, de DonatoP, SimonnotM O, et al. . Natural manganese oxide: Combined analytical approach for solid characterization and arsenic retention [J]. Geochimica et Cosmochimica Acta, 2005, 69(11): 2715-2724

[32]	DuQ, ZhangS-j, PanB-c, et al. . Bifunctional resin-ZVI composites for effective removal of arsenite through simultaneous adsorption and oxidation [J]. Water Research, 2013, 47(16): 6064-6074

[33]	BangS, JohnsonM D, KorfiatisG P, et al. . Chemical reactions between arsenic and zero-valent iron in water [J]. Water Research, 2005, 39(5): 763-770

[34]	ZhangS-j, LiX-y, ChenJ P. An XPS study for mechanisms of arsenate adsorption onto a magnetite-doped activated carbon fiber [J]. Journal of Colloid and Interface Science, 2010, 343(1): 232-238

[35]	ShanC, DongH, HuangP, et al. . Dual-functional millisphere of anion-exchanger-supported nanoceria for synergistic As(III) removal with stoichiometric H₂O₂: Catalytic oxidation and sorption [J]. Chemical Engineering Journal, 2019, 360: 982-989

[36]	MartinsonC A, ReddyK J. Adsorption of arsenic(III) and arsenic(V) by cupric oxide nanoparticles [J]. Journal of Colloid and Interface Science, 2009, 336(2): 406-411

[37]	BahlM K, WoodallR O, WatsonR L, et al. . Relaxation during photoemission and LMM Auger decay in arsenic and some of its compounds [J]. The Journal of Chemical Physics, 1976, 64(3): 1210-1218

[38]	FantauzziM, AtzeiD, ElsenerB, et al. . XPS and XAES analysis of copper, arsenic and sulfur chemical state in enargites [J]. Surface and Interface Analysis, 2006, 38(5): 922-930

[39]	YangK, QinW-q, LiuWei. Extraction of metal arsenic from waste sodium arsenate by roasting with charcoal powder [J]. Metals, 2018, 8(7): 542

[40]	YangK, QinW-q, LiuWei. Extraction of elemental arsenic and regeneration of calcium oxide from waste calcium arsenate produced from wastewater treatment [J]. Minerals Engineering, 2019, 134309-316