Natural soil genesis in red mud and underlying microbial mechanism.

doi:10.13287/j.1001-9332.202104.038

Abstract

Abstract: Soil genesis is important for ecological restoration of red mud disposal area. Soil genesis of red mud and the microbial mechanism were studied by analyzing the change of physicochemical and biochemical characteristics of red mud. We analyzed the microbial community structure in a red mud disposal area without any human-induced restoration through a space for time substitution approach. The results showed that, with the increases of storage time, the physical parameters of porosity, water-stable aggregates content, and mean weight diameter increased, but the bulk density decreased. The chemical parameters, including pH, electrical conductivity, acid neutralizing capacity, and exchangeable sodium percentage, decreased with increasing storage time. The bio-chemical parameters of total organic carbon, total nitrogen, available phosphorus, microbial biomass carbon and basal respiration increased, but the metabolic quotient decreased. The Shannon diversity index increased, and the dominant microflora in red mud changed from the oxygenic photosynthetic bacteria Cyanobacteria and thanaerobic anoxygenic phototrophic bacteria Chlorobi and Chloroflexi to Proteobacteria, Actinobacteria and Firmicutes. The ratio between eutrophic and oligotrophic bacteria substantially increased. The micromorphology results showed that the microorga-nism-red mud aggregates were formed through adsorption, linkage, intertwinement and package between red mud particles, microbial cells and their metabolites. The red mud biotope changed spontaneously from extreme and oligotrophic into soil-like under natural stockpiling. The soil genesis process was mediated by microbes through increasing nutrient level, decreasing alkalinity and sali-nity, and improving soil structure.

Key words: red mud, bauxite residue, soil genesis, microbial diversity, ecological restoration, primary succession

LI Hui, QU Yang, YAO Min-jie, TIAN Wen-jie, WANG Xiao-qing, SHI Ben, CAO Li-na, YUE Ling-fan, CAO Kai-qin. Natural soil genesis in red mud and underlying microbial mechanism.[J]. Chinese Journal of Applied Ecology, 2021, 32(4): 1452-1460.

References

[1] Xue SG, Kong X, Zhu F, et al. Proposal for management and alkalinity transformation of bauxite residue in China. Environmental Science and Pollution Research, 2016, 23: 12822-12834
[2] Qu Y, Li H, Tian WJ, et al. Leaching of valuable metals from red mud via batch and continuous processes by using fungi. Minerals Engineering, 2015, 81: 1-4
[3] Gräfe M, Klauber C. Bauxite residue issues: IV. Old obstacles and new pathways for in situ residue bioreme-diation. Hydrometallurgy, 2011, 108: 46-59
[4] 薛生国, 朱峰, 吴川, 等. 氧化铝赤泥堆场自然风化过程的土壤发生研究. 第六届重金属污染防治及风险评价研讨会. 厦门, 2015: 298-304 [Xue S-G, Zhu F, Wu C, et al. Soil genesis of natural weathering process in bauxite residue yard. The Sixth Research Conferences of Pollution Control and Rish Assessment of Heavy Metals. Xiamen, 2015: 298-304]
[5] 郭颖, 李玉冰, 薛生国, 等. 广西某赤泥堆场周边土壤重金属污染风险. 环境科学, 2018, 39(7): 3349-3357 [Guo Y, Li Y-B, Xue S-G, et al. Risk analysis of heavy metal contamination in farmland soil around a bauxite residue disposal area in Guangxi. Environmental Science, 2018, 39(7): 3349-3357]
[6] Schmalenberger A, Sullivan O, Gahan J, et al. Bacte-rial communities established in bauxite residues with different restoration histories. Environmental Science and Technology, 2013, 47: 7110-7119
[7] Williams C, Steinbergs A. Soil sulphur fractions as chemical indices of available sulphur in some Australian soils. Australian Journal of Agricultural Research, 1959, 10: 340-352
[8] Santini TC, Fey MV. Spontaneous vegetation encroachment upon bauxite residue (red mud) as an indicator and facilitator of in situ remediation processes. Environmental Science and Technology, 2013, 47: 12089-12096
[9] Jones BE, Haynes RJ, Phillips IR. Effect of amendment of bauxite processing sand with organic materials on its chemical, physical and microbial properties. Journal of Environmental Management, 2010, 91: 2281-2288
[10] Jones BE, Haynes RJ, Phillips IR. Addition of an organic amendment and/or residue mud to bauxite residue sand in order to improve its properties as a growth medium. Journal of Environmental Management, 2012, 95: 29-38
[11] Courtney R, Kirwanb L. Gypsum amendment of alkaline bauxite residue: Plant available aluminium and implications for grassland restoration. Ecological Engineering, 2012, 42: 279-282
[12] Zhu F, Xue S, Hartley W, et al. Novel predictors of soil genesis following natural weathering processes of bauxite residues. Environmental Science and Pollution Research, 2016, 23: 2856-2863
[13] Bradshaw A. Restoration of mined lands: Using natural processes. Ecological Engineering, 1997, 8: 255-269
[14] Bradshaw A. The use of natural processes in reclamation-advantages and difficulties. Landscape and Urban Planning, 2000, 51: 89-100
[15] Harris J. Soil microbial communities and restoration ecology: Facilitators or followers? Science, 2009, 325: 573-574
[16] Santini TC, Warren LA, Kendra KE. Microbial diversity in engineered haloalkaline environments shaped by shared geochemical drivers observed in natural analogues. Applied Environmental Microbiology, 2015, 81: 5026-5036
[17] Liao J, Jiang J, Xue S, et al. A novel acid-producing fungus isolated from bauxite residue: The potential to reduce the alkalinity. Geomicrobiology Journal, 2018, 35: 840-847
[18] Anam GB, Reddy MS, Ahn YH. Characterization of Trichoderma asperellum RM-28 for its sodic/saline-alkali tolerance and plant growth promoting activities to alle-viate toxicity of red mud. Science of the Total Environment, 2019, 662: 462-469
[19] Banning NC, Phillips IR, Jones DL, et al. Development of microbial diversity and functional potential in bauxite residue sand under rehabilitation. Restoration Ecology, 2011, 19: 78-87
[20] Krishna P, Babu AG, Reddy MS. Bacterial diversity of extremely alkaline bauxite residue site of alumina industrial plant using culturable bacteria and residue 16S rRNA gene clones. Extremophiles, 2014, 18: 665-676
[21] Nyenda T, Gwenzi W, Piyob TT, et al. Occurrence of biological crusts and their relationship with vegetation on a chronosequence of abandoned gold mine tailings. Ecological Engineering, 2019, 139: 1-10
[22] 李毳, 景炬辉, 刘晋仙, 等. 十八河铜尾矿库坝面细菌群落时空动态及其驱动力. 应用生态学报, 2018, 29(6): 1975-1982 [Li C, Jing J-H, Liu J-X, et al. Spatiotemporal dynamics and driving forces of soil bacterial communities on the dam of Shibahe copper mine tailings in Shanxi, China. Chinese Journal of Applied Ecology, 2018, 29(6): 1975-1982]
[23] 王彩云, 武春成, 曹霞, 等. 生物炭对温室黄瓜不同连作年限土壤养分和微生物群落多样性的影响. 应用生态学报, 2019, 30(4): 1359-1366 [Wang C-Y, Wu C-C, Cao X, et al. Effects of biochar on soil nutrition and microbial community diversity under continuous cultivated cucumber soils in greenhouse. Chinese Journal of Applied Ecology, 2019, 30(4): 1359-1366]
[24] 傅敏, 郝敏敏, 胡恒宇, 等. 土壤有机碳和微生物群落结构对多年不同耕作方式与秸秆还田的响应. 应用生态学报, 2019, 30(9): 3183-3194 [Fu M, Hao M-M, Hu H-Y, et al. Responses of soil organic carbon and microbial community structure to different tillage patterns and straw returning for multiple years. Chinese Journal of Applied Ecology, 2019, 30(9): 3183-3194]
[25] 鲍士旦. 土壤农化分析. 北京: 中国农业出版社, 2000 [Bao S-D. Soil Agrochemistry Analysis. Beijing: China Agriculture Press, 2000]
[26] Courtney R, Xue SG. Rehabilitation of bauxite residue to support soil development and grassland establishment. Journal of Central South University, 2019, 26: 353-360
[27] Khaitan S, Dzombak DA, Lowry GV. Chemistry of the acid neutralization capacity of bauxite residue. Environmental Engineering Science, 2009, 26: 873-881
[28] Qu Y, Li H, Wang XQ, et al. Selective parameters and bioleaching kinetics for leaching vanadium from red mud using Aspergillus niger and Penicillium tricolor. Mine-rals, 2019, 9: 697-705
[29] Qu Y, Li H, Wang XQ, et al. Bioleaching of major, rare earth, and radioactive elements from red mud by using indigenous chemoheterotrophic bacterium Acetobacter sp. Minerals, 2019, 9: 67-74
[30] Yao MJ, Rui J, Li J, et al. Rate-specific responses of prokaryotic diversity and structure to nitrogen deposition in the Leymus chinensis steppe. Soil Biology and Biochemistry, 2014, 79: 81-90
[31] Qu Y, Lian B. Bioleaching of rare earth and radioactive elements from red mud using Penicillium tricolor RM-10. Bioresource Technology, 2013, 136: 16-23
[32] Brochier C, Boussau B, Gribaldo S, et al. Mesophilic crenarchaeota: Proposal for a third archaeal phylum, the Thaumarchaeota. Nature Reviews Microbiology, 2008, 6: 245-252
[33] Leyn SA, Rodionova IA, Li X, et al. Novel transcriptional regulons for autotrophic cycle genes in Crenarchaeota. Journal of Bacteriology, 2015, 197: 2383-2391
[34] Schmid J, Koenig S, Pick A, et al. Draft genome sequence of Kozakia baliensis SR-745, the first sequenced Kozakia strain from the family Acetobacteraceae. Genome Announcements, 2014, 2: 594-614
[35] Hsu YH, Lai WA, Lin SY, et al. Chiayiivirga flava gen. nov., sp. nov., a novel bacterium of the family Xanthomonadaceae isolated from an agricultural soil, and emended description of the genus Dokdonella. International Journal of Systematic and Evolutionary Micro-biology, 2013, 63: 3293-3300