Regional-scale investigation of salt ions distribution characteristics in bauxite residue: A case study in a disposal area

Sheng-guo Xue; Qiong-li Wang; Tao Tian; Yu-zhen Ye; Yi-fan Zhang; Feng Zhu

doi:10.1007/s11771-019-4014-x

Journal of Central South University ›› 2019, Vol. 26 ›› Issue (2) : 422 -429. DOI: 10.1007/s11771-019-4014-x

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Regional-scale investigation of salt ions distribution characteristics in bauxite residue: A case study in a disposal area

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Abstract

Revegetation on bauxite residue disposal areas is the most promising strategy to reduce its potential ecological risk during stacking or disposing. Migration of salt ions in bauxite residue is one of the major issues to stimulate soil formation to support plant growth. 21 residue samples were collected and the related parameters including exchangeable cations, soluble ions, total salt, pH, electrical conductivity (EC) and exchangeable sodium percentage (ESP) were selected to evaluate alkalization and salinization of bauxite residue. High levels of ions, cation exchange capacity (TOC), total salt, exchangeable sodium percentage (ESP) and cation exchange capacity (CEC) in bauxite residue were detected with greater coefficient of variation (CV), which indicated that distribution characteristics of salt ions varied significantly. The percentage of sulfate-chloride-soda type in the residues accounted for 71.43%. The mean value of pH was 10.10, whilst mean value of ESP was 52.05%. It indicated that the residues in this case study belonged to sulfate-chloride-soda saline and alkaline soil. The research results could provide theoretical basis for soil formation in bauxite residue.

Keywords

bauxite residue / bauxite residue disposal area / salt / saline-alkali soil / soil formation in bauxite residue

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Sheng-guo Xue, Qiong-li Wang, Tao Tian, Yu-zhen Ye, Yi-fan Zhang, Feng Zhu. Regional-scale investigation of salt ions distribution characteristics in bauxite residue: A case study in a disposal area. Journal of Central South University, 2019, 26(2): 422-429 DOI:10.1007/s11771-019-4014-x

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References

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[1]	JonesB E H, HaynesR J. Bauxite processing residue: A critical review of its formation, properties, storage, and revegetation [J]. Critical Reviews in Environmental Science & Technology, 2011, 41(3): 271-315

[2]	XueS, KongX, ZhuF, HartleyW, LiX, LiYi. Proposal for management and alkalinity transformation of bauxite residue in China [J]. Environmental Science & Pollution Research, 2016, 23(13): 12822-12834

[3]	ZhuF, LiaoJ, XueS, HartleyW, ZouQ, WuHao. Evaluation of aggregate microstructures following natural regeneration in bauxite residue as characterized by synchrotron-based X-ray micro-computed tomography [J]. Science of the Total Environment, 2016, 573(24): 155-163

[4]	GrafeM, PowerG, KlauberC. Bauxite residue issues: III. Alkalinity and associated chemistry [J]. Hydrometallurgy, 2011, 108(12): 60-79

[5]	LiuW, ChenX, LiW, YuY, YanKun. Environmental assessment, management and utilization of red mud in China [J]. Journal of Cleaner Production, 2014, 84: 606-610

[6]	KongX, GuoY, XueS, HartleyW, WuC, YeY, ChengQin. Natural evolution of alkaline characteristics in bauxite residue [J]. Journal of Cleaner Production, 2017, 143: 224-230

[7]	GelencserA, KovatsN, TurocziB, RostasiH A, ImreK, NyiroK I, CsakberenyiM D, TothC A. The Red Mud Accident in Ajka (Hungary): Characterization and potential health effects of fugitive dust [J]. Environmental Science & Technology, 2011, 45(4): 1608-1615

[8]	ZhuF, XueS, HartleyW, HuangL, WuC, LiXiao. Novel predictors of soil genesis following natural weathering processes of bauxite residues [J]. Environmental Science & Pollution Research, 2016, 23(3): 2856-2863

[9]	SantiniT C, BanningN C. Alkaline tailings as novel soil forming substrates: Reframing perspectives on mining and refining wastes [J]. Hydrometallurgy, 2016, 164: 38-47

[10]	KongX-F, TianT, XueS, HartleyW, HuangL, WuC, LiChu. Development of alkaline electrochemical characteristics demonstrates soil formation in bauxite residue undergoing natural rehabilitation [J]. Land Degradation and Development, 2018, 29(1): 58-67

[11]	ZhuF, LiX, XueS, HartleyW, WuC, HanFu. Natural plant colonization improves the physical condition of bauxite residue over time [J]. Environmental Science and Pollution Research, 2016, 23(22): 22897-22905

[12]	ZhuF, ChengQ, XueS, LiC, HartleyW, WuC, TianTao. Influence of natural regeneration on fractal features of residue microaggregates in bauxite residue disposal areas [J]. Land Degradation & Development, 2018, 29(1): 138-149

[13]	BanningN C, SawadaY, PhillipsI R, MurphyD V. Amendment of bauxite residue sand can alleviate constraints to plant establishment and nutrient cycling capacity in a water-limited environment [J]. Ecological Engineering, 2014, 62(1): 179-187

[14]	XeuS, YeY, ZhuF, WangQ, JiangJ, HartleyW. Changes in distribution and microstructure of bauxite residue aggregates following amendments addition [J]. Journal of Environmental Sciences, 2019, 78: 276-286

[15]	AndrewW B, DouglasI S, RonanC, SimonP R, PaulN H, WilliamM M, IanT B. Sustained bauxite residue rehabilitation with gypsum and organic matter 16 years after initial treatment [J]. Environmental Science & Technology, 2018, 52(1): 152-161

[16]	ZhuF, HouJ, XeuS, WuC, WangQ, HartleyW. Vermicompost and gypsum amendments improve aggregate formation in bauxite residue [J]. Land Degradation & Development, 2017, 28(7): 2109-2120

[17]	ZhaoJ, ChenS, HuR, LiYa. Aggregate stability and size distribution of red soils under different land uses integrally regulated by soil organic matter, and iron and aluminum oxides [J]. Soil & Tillage Research, 2017, 167: 73-79

[18]	ShiP, ArterC, LiuX, KellerM, SchulinR. Soil aggregate stability and size-selective sediment transport with surface runoff as affected by organic residue amendment [J]. Science of the Total Environment, 2017607608

[19]	WuX, CaiC, WangJun. Spatial variations of aggregate stability in relation to sesquioxides for zonal soils, South-central China [J]. Soil & Tillage Research, 2016, 157: 11-22

[20]	XueS, WuY, LiY, KongX, ZhuF, HartleyW, LiXiao. Industrial wastes applications for alkalinity regulation in bauxite residue: A comprehensive review [J]. Journal of Central South University, 2019, 26(2): 268-288

[21]	LevyJ G, TorrentoR J. Clay dispersion and macroaggregate stability as affected by exchangeable potassium and sodium [J]. Soil science, 1995, 160(5): 352-358

[22]	XueS, LiM, JiangJ M G J, LiC, KongXiang. Phosphogypsum stabilization of bauxite residue: Conversion of its alkaline characteristics [J]. Journal of Environmental Sciences, 2019, 77: 1-10

[23]	LiY, JiangJ, XueS, MillarG, KongX-f, LiX, LiM, LiChu. Effect of ammonium chloride on leaching behavior of alkaline anion and sodium ion in bauxite residue [J]. Transactions of Nonferrous Metals Society of China, 2018, 28(10): 2125-2134

[24]	JonesB E H, HaynesR J, PhillipsI R. Influence of organic waste and residue mud additions on chemical, physical and microbial properties of bauxite residue sand [J]. Environmental Science and Pollution Research, 2011, 18(2): 199-211

[25]	MartinA M, ForteG, OstapS, SeeJ. The mineralogy of bauxite for producing smelter-grade alumina [J]. Mineralogy Overview, 2001, 12(1253): 36-40

[26]	KilicK, KilicS. Spatial variability of salinity and alkalinity of a field having salination risk in semi-arid climate in northern Turkey [J]. Environmental Monitoring and Assessment, 2007, 127(1–3): 55-65

[27]	ReevesD W. The role of soil organic matter in maintaining soil quality in continuous cropping systems [J]. Soil & Tillage Research, 1997, 43(1): 131-167

[28]	PalD K, BhattacharyyaT, RayS K, ChandranP, SrivastavaP, DurgeS L, BhuseS R. Significance of soil modifiers (Ca-zeolites and gypsum) in naturally degraded Vertisols of the Peninsular India in redefining the sodic soils [J]. Geoderma, 2006, 136(12): 210-228

[29]	MeiJ P, ChenL. Fuzzy clustering with weighted medoids for relational data [J]. Pattern Recognition, 2010, 43(5): 1964-1974

[30]	LuRuSoil agrochemical analysis methods [M], 1999, Nanjing, China Agricultural Science and Technology Press

[31]	MorR P, ManchandaH R. Influence of phosphorus on the tolerance of table pea to chloride and sulfate salinity in a sandy soil [J]. Arid Soil Research and Rehabilitation, 1992, 6: 41-52