Determination of Various Forms of Iron and Manganese Oxides and the Main Controlling Factors of Absorption of Sb(Ⅲ) in Soil

CUI Ting; YE Xin; ZHU Xiaping; LI Junya; XU Huan

doi:10.15898/j.cnki.11-2131/td.202111250187

2023 Vol. 42, No. 1

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CUI Ting, YE Xin, ZHU Xiaping, LI Junya, XU Huan. Determination of Various Forms of Iron and Manganese Oxides and the Main Controlling Factors of Absorption of Sb(Ⅲ) in Soil[J]. Rock and Mineral Analysis, 2023, 42(1): 167-176. doi: 10.15898/j.cnki.11-2131/td.202111250187

Citation:

CUI Ting, YE Xin, ZHU Xiaping, LI Junya, XU Huan. Determination of Various Forms of Iron and Manganese Oxides and the Main Controlling Factors of Absorption of Sb(Ⅲ) in Soil[J]. Rock and Mineral Analysis, 2023, 42(1): 167-176. doi: 10.15898/j.cnki.11-2131/td.202111250187

Determination of Various Forms of Iron and Manganese Oxides and the Main Controlling Factors of Absorption of Sb(Ⅲ) in Soil

1.
College of Materials and Chemistry & Chemical Engineering, Chengdu University of Technology, Chengdu 610059, China
2.
The 405 Geological Brigade, Sichuan Bureau of Geology and Mineral Exploration & Development, Dujiangyan 611830, China

More Information

Corresponding authors: ZHU Xiaping, zhuxiaping@cdut.edu.cn ; LI Junya, 1092956259@qq.com

Received Date: 25 November 2021

Revised Date: 04 January 2022

Accepted Date: 30 January 2022

Publish Date: 28 January 2023

Abstract

Abstract

BACKGROUND
It is of great significance for evaluation, early warning and remediation of antimony contaminated soil to study the sorption factors affecting Sb(Ⅲ) adsorption in soil.
OBJECTIVES
To investigate the forms of Fe and Mn oxides and controlling factors of Sb(Ⅲ) adsorption in soil.
METHODS
The physicochemical properties, mechanical composition, and main chemical composition of soils from 10 different areas were determined by chemical method, inductively coupled plasma-optical emission spectrometry and atomic fluorescence spectrometry. The contents of different forms of iron and manganese and the saturated adsorption capacity of soils to Sb(Ⅲ) were determined by atomic absorption spectrometry. The correlation analysis, principal component analysis and factor analysis of soil saturated adsorption capacity to Sb(Ⅲ), soil physicochemical properties, mechanical composition, iron and manganese oxides and their forms were carried out by SPSS 21.0.
RESULTS
On the basis of studying the influencing factors of soil adsorption of Sb(Ⅲ), the main controlling factors were further studied. The saturated adsorption capacity of soil to Sb(Ⅲ) was between 0.63mg/g and 3.98mg/g, and was related to soil type with the order of red soil>brown soil>yellow soil>cinnamon soil>sandy soil. According to the correlation analysis results, the saturated adsorption capacity of soil to Sb(Ⅲ) was significantly positively correlated with cation exchange capacity, total iron oxide, amorphous iron content, and was positively correlated with free iron content, amorphous manganese content and free manganese content. The principal component analysis and factor analysis showed that these six factors were the main controlling factors affecting the adsorption of Sb(Ⅲ) in soil, and the influence degree was: total iron oxide>cation exchange capacity>amorphous iron content>free iron content>amorphous manganese content>free manganese content.
CONCLUSIONS
The adsorption capacity of soil to Sb(Ⅲ) is significantly affected by the total amount of iron and manganese oxides and their forms.
- soil /
- Sb(Ⅲ) /
- absorption /
- main controlling factors /
- iron manganese oxide forms /
- atomic absorption spectrometry

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References

[1]	Deng R J, Shao R, Ren B Z, et al. Adsorption of antimony(Ⅲ) onto Fe(Ⅲ)-treated humus sludge adsorbent: Behavior and mechanism insights[J]. Polish Journal of Environmental Studies, 2019, 28(2): 577-586. Google Scholar
[2]	He M C, Wang N N, Long X J, et al. Antimony speciation in the environment: Recent advances in understanding the biogeochemical processes and ecological effects[J]. Journal of Environmental Sciences, 2019, 75: 14-39. doi: 10.1016/j.jes.2018.05.023 CrossRef Google Scholar
[3]	Zhu Y M, Wu Q H, Lv H Q, et al. Toxicity of different forms of antimony to rice plants: Effects on reactive oxidative species production, antioxidative systems, and uptake of essential elements[J]. Environmental Pollution, 2020, 263: 114544. doi: 10.1016/j.envpol.2020.114544 CrossRef Google Scholar
[4]	Mbadugha L, Cowper D, Dossanov S, et al. Geogenic and anthropogenic interactions at a former Sb mine: Environmental impacts of As and Sb[J]. Environmental Geochemistry Health, 2020, 42: 3911-3924. doi: 10.1007/s10653-020-00652-w CrossRef Google Scholar
[5]	张龙, 宋波, 黄凤艳, 等. 湖南锡矿山周边土壤-农作物系统锑迁移转换特征及污染评价[J]. 环境科学, 2022, 43(3): 1558-1566. doi: 10.13227/j.hjkx.202105162 CrossRef Google Scholar Zhang L, Song B, Huang F Y, et al. Characteristics of antimony migration and transformation and pollution evaluation in soil-crop system around tin mine in Hunan Province[J]. Environmental Science, 2022, 43(3): 1558-1566. doi: 10.13227/j.hjkx.202105162 CrossRef Google Scholar
[6]	Verbeeck M, Thiry Y, Smolders E. Soil organic matter affects arsenic and antimony sorption in anaerobic soils[J]. Environmental Pollution, 2020, 257: 113566. doi: 10.1016/j.envpol.2019.113566 CrossRef Google Scholar
[7]	刘冬, 贺灵, 文雪琴, 等. 金衢盆地典型地区土壤-稻米重金属含量及土壤酸碱度的影响研究[J]. 岩矿测试, 2021, 40(6): 883-893. doi: 10.15898/j.cnki.11-2131/td.20211100139 CrossRef Google Scholar Liu D, He L, Wen X Q, et al. Concentration and relationship about heavy metals in soils and rices and influencing of pH in Jinqu Basin[J]. Rock and Mineral Analysis, 2021, 40(6): 883-893. doi: 10.15898/j.cnki.11-2131/td.20211100139 CrossRef Google Scholar
[8]	岑如香, 张旺, 韦小了, 等. 黔产薏苡仁及其产地土壤重金属污染的特征[J]. 水土保持通报, 2021, 41(1): 103-111. Google Scholar Cen R X, Zhang W, Wei X L, et al. Characteristics of heavy metal pollution of coix seed and soil from its producing area in Guizhou Province[J]. Bulletin of Soil and Water Conservation, 2021, 41(1): 103-111. Google Scholar
[9]	代豫杰, 郭建英, 董智, 等. 不同沙生灌木下土壤颗粒及重金属空间分布特征[J]. 环境科学, 2017, 38(11): 4809-4818. doi: 10.13227/j.hjkx.201704135 CrossRef Google Scholar Dai Y J, Guo J Y, Dong Z, et al. Spatial distribution of soil particles and heavy metals under different psammophilicshrubs in the Ulan Buh Desert[J]. Environmental Science, 2017, 38(11): 4809-4818. doi: 10.13227/j.hjkx.201704135 CrossRef Google Scholar
[10]	周世伟, 朱丽娜, 贺京哲, 等. 锑/磷在膨润土和高岭土的竞争吸附[J]. 土壤, 2017, 49(3): 492-499. doi: 10.13758/j.cnki.tr.2017.03.010 CrossRef Google Scholar Zhou S W, Zhu L, He J Z, et al. Competition adsorption of antimony (Sb) and phosphorus (P) on bentonite and kaolinite[J]. Soils, 2017, 49(3): 492-499. doi: 10.13758/j.cnki.tr.2017.03.010 CrossRef Google Scholar
[11]	Verbeeck M, Warrinnier R, Gustafsson J P, et al. Soil organic matter increases antimonate mobility in soil: An Sb(OH)₆ sorption and modelling study[J]. Applied Geochemistry, 2019, 104: 33-41. doi: 10.1016/j.apgeochem.2019.03.012 CrossRef Google Scholar
[12]	Steely S, Amarasiriwardena D, Xing B. An investigation of inorganic antimony species and antimony associated with soil humic acid molar mass fractions in contaminated soils[J]. Environmental Pollution, 2007, 148: 590-598. doi: 10.1016/j.envpol.2006.11.031 CrossRef Google Scholar
[13]	Rong Q, Zhang C L, Huang H, et al. Immobilization of As and Sb by combined applications Fe-Mn oxides with organic amendments and alleviation their uptake by brassica campestris L. [J]. Journal of Cleaner Production, 2021, 288: 125088. doi: 10.1016/j.jclepro.2020.125088 CrossRef Google Scholar
[14]	Lan B Y, Wang Y X, Wang X, et al. Aqueous arsenic (As) and antimony (Sb) removal by potassium ferrate[J]. Chemical Engineering Journal, 2016, 292: 389-397. doi: 10.1016/j.cej.2016.02.019 CrossRef Google Scholar
[15]	王鑫浩. 不同晶型MnO₂吸附剂对水中铊及锑的吸附效果研究[D]. 西安: 西安工程大学, 2018: 43. Google Scholar Wang X H. Study on the adsorption effect of different crystalline MnO₂ adsorbents on thallium and antimony in water[D]. Xi'an: Xi'an Polytechnic University, 2018: 43. Google Scholar
[16]	Wang H W, Tsang Y F, Wang Y N, et al. Adsorption capacities of poorly crystalline Fe minerals for antimonate and arsenate removal from water: Adsorption properties and effects of environmental and chemical conditions[J]. Clean Technologies and Environmental Policy, 2018, 20: 2169-2179. doi: 10.1007/s10098-018-1552-0 CrossRef Google Scholar
[17]	Shanggan Y X, Qin X P, Zhao L, et al. Effects of iron oxide on antimony(Ⅴ) adsorption in natural soils: Transmission electron microscopy and X-ray photoelectron spectroscopy measurements[J]. Journal of Soils & Sediments, 2016, 16(2): 509-517. Google Scholar
[18]	白德奎, 朱霞萍, 王艳艳, 等. 氧化锰、氧化铁、氧化铝对砷(Ⅲ)的吸附行为研究[J]. 岩矿测试, 2010, 29(1): 55-60. doi: 10.3969/j.issn.0254-5357.2010.01.013 CrossRef Google Scholar Bai D K, Zhu X P, Wang Y Y, et al. Study on adsorption behaviors of As(Ⅲ) by manganese oxide iron oxide and aluminium oxide[J]. Rock and Mineral Analysis, 2010, 29(1): 55-60. doi: 10.3969/j.issn.0254-5357.2010.01.013 CrossRef Google Scholar
[19]	Guo X J, Wu Z J, He M C, et al. Adsorption of antimony onto iron oxyhydroxides: Adsorption behavior and surface structure[J]. Journal of Hazardous Materials, 2014, 276: 339-345. doi: 10.1016/j.jhazmat.2014.05.025 CrossRef Google Scholar
[20]	刘爱叶, 马杰, 马光胜. 氯化铵-乙醇法测定膨胀土阳离子交换量方法的优化[J]. 铁道勘察, 2011, 37(1): 43-45. doi: 10.3969/j.issn.1672-7479.2011.01.014 CrossRef Google Scholar Liu A Y, Ma J, Ma G S. Optimized experiment for ammonium chloride-ethanol method in measurement of bentonite cationic exchange capacity[J]. Railway Investigation and Surveying, 2011, 37(1): 43-45. doi: 10.3969/j.issn.1672-7479.2011.01.014 CrossRef Google Scholar
[21]	徐永昊, 聂军, 鲁艳红, 等. 减施化肥下紫云英翻压量对土壤团聚体及铁锰氧化物的影响[J]. 中国土壤与肥料, 2020(6): 9-18. Google Scholar Xu Y H, Nie J, Lu Y H, et al. Effects of different returning amount of Chinese milk vetch on soil aggregates and iron and manganese oxides under reduced fertilizer application[J]. Soil and Fertilizer Sciences in China, 2020(6): 9-18. Google Scholar
[22]	顾明华, 李志明, 陈宏, 等. 施锰对土壤锰氧化物形成及镉固定的影响[J]. 生态环境学报, 2020, 29(2): 360-368. Google Scholar Gu M H, Li Z M, Chen H, et al. Effects of manganese application on the formation of manganese oxides and cadmium fixation in soil[J]. Ecology and Environmental Sciences, 2020, 29(2): 360-368. Google Scholar
[23]	姜学钧. 海洋铁锰氧化物沉积物中常、微量元素的地球化学特征[D]. 青岛: 中国海洋大学, 2008: 22. Google Scholar Jiang X J. Geochemistry of major and minor elements in marine ferromanganese oxide deposits[D]. Qingdao: Ocean University of China, 2008: 22. Google Scholar
[24]	郑智慷, 曾江萍, 王家松, 等. 常压密闭微波消解-电感耦合等离子体发射光谱法测定锑矿石中的锑[J]. 岩矿测试, 2020, 39(2): 208-215. Google Scholar Zheng Z K, Zeng J P, Wang J S, et al. Determination of antimony in antimony ores by inductively coupled plasma-optical emission spectrometry with microwave digestion[J]. Rock and Mineral Analysis, 2020, 39(2): 208-215. Google Scholar
[25]	薛佳. 液相色谱-原子荧光光谱联用法测定土壤砷铬锑硒元素价态[J]. 岩矿测试, 2021, 40(2): 250-261. Google Scholar Xue J. Determination of valences of As, Cr, Sb and Se in soil using HPLC-HG-AFS[J]. Rock and Mineral Analysis, 2021, 40(2): 250-261. Google Scholar
[26]	谭迪. 锑砷复合污染土壤的风险评价及萃取研究[D]. 长沙: 湖南农业大学, 2019: 2. Google Scholar Tan D. Risk assessment and leaching extraction of antimony (Sb) and arsenic (As) contaminated soils[D]. Changsha: Hunan Agricultural University, 2019: 2. Google Scholar
[27]	马祥爱, 秦俊梅, 张亚尼. 锑在不同土壤中的解吸行为比较[J]. 农业环境科学学报, 2015, 34(8): 1528-1534. Google Scholar Ma X A, Qin J M, Zhang Y N. A comparison of desorption behaviors of Sb in different soils[J]. Journal of Agro-Environment Science, 2015, 34(8): 1528-1534. Google Scholar
[28]	Zhu Y M, Yang J G, Wang L Z, et al. Factors influencing the uptake and speciation transformation of antimony in the soil-plant system, and the redistribution and toxicity of antimony in plants[J]. Science of the Total Environment, 2020, 738: 140232. Google Scholar
[29]	姜再菊. 锑矿冶炼区周围土壤中锑的吸附释放行为研究[D]. 贵阳: 贵州大学, 2019: 7. Google Scholar Jiang Z J. Study on adsorption and release behavior of Sb in soil of antimony ore smelting mine[D]. Guiyang: Guizhou University, 2019: 7. Google Scholar
[30]	Lin X L, He F, Sun Z J, et al. Influences of soil pro-perties and long-time aging on phytotoxicity of antimony to barley root elongation[J]. Environmental Pollution, 2020, 262: 114330. Google Scholar
[31]	孙雪. 不同景观部位土壤铁锰新生体的形态, 组成及形成环境研究[D]. 沈阳: 沈阳农业大学, 2018: 4-5. Google Scholar Sun X. The morphology, composition, and formation environment of soil Fe-Mn new growth in different landscape sites[D]. Shenyang: Shenyang Agricultural University, 2018: 4-5. Google Scholar
[32]	肖作义, 马耀祖, 郑春丽, 等. 季节性冻融作用对土壤吸附稀土元素镧的影响[J]. 应用化工, 2018, 47(9): 1841-1845. Google Scholar Xiao Z Y, Ma Y Z, Zheng C L, et al. The effect of seasonal freeze-thaw on the soil adsorption of rare earth elements lanthanum[J]. Applied Chemical Industry, 2018, 47(9): 1841-1845. Google Scholar
[33]	梁化学. 不同形态氧化铁对黄土性土壤表面性质及铅吸附解吸的影响[D]. 杨凌: 西北农林科技大学, 2016: 2-3. Google Scholar Liang H X. Effects of iron oxides on surface properties and adsorption-desorption of lead by several loessial soils[D]. Yangling: Northwest A&F University, 2016: 2-3. Google Scholar
[34]	Zhou S, Sato T, Otake T. Dissolved silica effects on adsorption and co-precipitation of Sb(Ⅲ) and Sb(Ⅴ) with ferrihydrite[J]. Minerals, 2018, 8(101): 1-12. Google Scholar
[35]	Qi P F, Pichler T. Sequential and simultaneous adsorption of Sb(Ⅲ) and Sb(Ⅴ) on ferrihydrite: Implications for oxidation and competition[J]. Chemosphere, 2016, 145: 55-60. Google Scholar
[36]	高雪. 外源砷在土壤中的老化及植物有效性研究[D]. 北京: 中国农业科学院, 2016: 21. Google Scholar Gao X. A study on aging process and phytoavailability of exogenous arsenic in soils[D]. Beijing: Chinese Academy of Agricultural Sciences, 2016: 21. Google Scholar
[37]	Cai Y B, Mi Y T, Zhang H, et al. Kinetic modeling of antimony(Ⅲ) oxidation and sorption in soils[J]. Journal of Hazardous Materials, 2016, 316: 102-109. Google Scholar
[38]	Long X J, Wang X, Guo X J, et al. A review of removal technology for antimony in aqueous solution[J]. Journal of Environmental Sciences, 2020, 90: 189-204. Google Scholar
[39]	Belzile N, Chen Y W, Wang Z J. Oxidation of antimony(Ⅲ) by amorphous iron and manganese oxyhydroxides[J]. Chemical Geology, 2001, 174: 379-387. Google Scholar