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Journal of Soils and Sediments

, Volume 19, Issue 2, pp 798–808 | Cite as

Effects of water and organic manure coupling on the immobilization of cadmium by sepiolite

  • Yiyun Liu
  • Yingming XuEmail author
  • Xu Qin
  • Lijie Zhao
  • Qingqing Huang
  • Lin Wang
Soils, Sec 3 • Remediation and Management of Contaminated or Degraded Lands • Research Article
  • 83 Downloads

Abstract

Purpose

Natural sepiolite (SP) has proven effective on the in-situ immobilization remediation of Cd-contaminated soils. But the practical remediation effect may largely influenced by water management and the application of organic manure. The effects of chicken manure (CM) on SP-amended soils were investigated under normal and saturated water conditions using a pot experiment with Brassica campestris L.

Materials and methods

Cd-contaminated paddy soils were amended with CM, SP, and CM + SP with no amendment as control. The amount of sepiolite was 0.5% (w/w, the same below) either in SP or CM + SP amended soils, while the amount of CM was 0.5, 1.0, and 2.0% in CM and CM + SP-amended soils. The plant metal contents, fresh weight, and soluble sugar content of plant edible parts were measured on harvest. Soil Cd was extracted by diethylenetriaminepentaacetic acid (DTPA) and HCl to estimate the mobility of heavy metal. Soil pH and dissolved organic matter (DOM) of rhizosphere soil were determined. The electronegative charges of soils were also measured using the zeta potential.

Results and discussion

The application of CM and increasing soil moisture on SP-amended soil increased plant growth to a greater extent than the application of SP alone. The application of CM along with the increase of soil moisture decreased Cd uptake and translocation in plants grown on SP-amended soil compared to the application of SP alone. Cd content of edible plant parts reached a minimum of 0.24 mg kg−1 with the application of 2.0% CM on SP-amended soils under water-saturated conditions, which was approximately 50% lower than the Cd concentration found when applying SP alone.

Conclusions

The results of this study suggest that the application of sepiolite on Cd contaminated soil can effectively reduce Cd uptake by B. campestris L., and the addition of CM combined with effective water management also appears to further reduce Cd absorption and accumulation.

Keywords

Cadmium uptake Heavy metals Organic fertilizer Sepiolite-amended soil Water conditions 

Notes

Acknowledgments

We would like to thank Editage (www.editage.cn) for English language editing.

Funding information

The current research was supported by the Funds for Tianjin Science and Technology Support Plan Project (14ZCZDSF00004), Transformation and Popularization of Agricultural Scientific and Technological Achievements in Tianjin (201404100 and 201502290), the Science and Technology Innovation Project from the Chinese Academy of Agricultural Sciences (No. CAASXTCX-xym-2017), and the China Agriculture Research System (CARS-03).

References

  1. Bolan NS, Adriano DC, Duraisamy P et al (2003) Immobilization and phytoavailability of cadmium in variable charge soils. I. Effect of phosphate addition. Plant Soil 250(1):83–94CrossRefGoogle Scholar
  2. Bu R, Xiao X, Liao W, Hu Y, Li J, Lv J, Wang R, Xie J (2017) Exogenous Si alleviation of autotoxicity in cucumber (Cucumis sativus L.) seed germination is correlated with changes in carbohydrate metabolism. J Plant Growth Regul.  https://doi.org/10.1007/s00344-017-9773-8
  3. Cao X, Wahbi A, Ma L, Li B, Yang Y (2009) Immobilization of Zn, Cu, and Pb in contaminated soils using phosphate rock and phosphoric acid. J Hazard Mater 164:555–564CrossRefGoogle Scholar
  4. Crecchio C, Curci M, Pizzigallo MDR, Ricciuti P, Ruggiero P (2004) Effects of municipal solid waste compost amendments on soil enzyme activities and bacterial genetic diversity. Soil Biol Biochem 36(10):1595–1605CrossRefGoogle Scholar
  5. Cui YS, Wen LP (2013) Arsenate and phosphate adsorption in relation to oxides composition in soils: LCD modeling. Environ Sci Technol 47(13):7269–7276CrossRefGoogle Scholar
  6. Davranche M, Bollinger JC (2000) Heavy metals desorption from synthesized and natural iron and manganese oxyhydroxides: effect of reductive conditions. J Colloid Interf Sci 227(2):531–539CrossRefGoogle Scholar
  7. Fayiga AO, Ma LQ (2006) Using phosphate rock to immobilize metals in soil and increase arsenic uptake by hyperaccumulator Pteris vittata. Sci Total Environ 359:17–25CrossRefGoogle Scholar
  8. Fellet G, Marmiroli M, Marchiol L (2014) Elements uptake by metal accumulator species grown on mine tailings amended with three types of biochar. Sci Total Environ 468-469:598–608CrossRefGoogle Scholar
  9. Fulda B, Voegelin A, Ehlert K, Kretzschmar R (2013) Redox transformation, solid phase speciation and solution dynamics of copper during soil reduction and reoxidation as affected by sulfate availability. Geochim Cosmochim Acta 123:385–402CrossRefGoogle Scholar
  10. Gao J, Lv J, Wu H, Dai Y, Nasir M (2018) Impacts of wheat straw addition on dissolved organic matter characteristics in cadmium-contaminated soils: insights from fluorescence spectroscopy and environmental implications. Chemosphere 193:1027–1035CrossRefGoogle Scholar
  11. Garau G, Castaldi C, Santona L, Deiana P, Melis P (2007) Influence of red mud, zeolite and lime on heavy metal immobilization, culturable heterotrophic microbial populations and enzyme activities in a contaminated soil. Geoderma 142:47–57CrossRefGoogle Scholar
  12. Gondek and Mierzwa-Hersztek (2016) Effect of low-temperature biochar derived from pig manure and poultry litter on mobile and organic matter-bound forms of Cu, Cd, Pb and Zn in sandy soil. Soil Use Manage 32:357–367CrossRefGoogle Scholar
  13. Hansen V, Hauggaard-Nielsen H, Petersen CT, Mikkelsen TN, Müller-Stöver D (2016) Effects of gasification biochar on plant-available water capacity and plant growth in two contrasting soil types. Soil Till Res 161:1–9CrossRefGoogle Scholar
  14. Honma T, Ohba H, Kaneko A, Nakamura K, Makino T, Katou H (2016) Effects of soil amendments on arsenic and cadmium uptake by rice plants (Oryza sativa L. cv. Koshihikari) under different water management practices. Soil Sci Plant Nutr 62:349–356Google Scholar
  15. Hofaker AF, Voegelin A, Kaegi R et al (2013) Temperature-dependent formation of metallic copper and metal sulfide nanoparticles during flooding of a contaminated soil. Geochim Cosmochim Ac 103:316–332CrossRefGoogle Scholar
  16. Huang H, Yan J, Sun GX et al (2012) Arsenic speciation and volatilization from flooded paddy soils amended with different organic matters. Environ Sci Technol 46:2163–2168CrossRefGoogle Scholar
  17. Huang Y, Zhu Y, Tong Y, Hu Y, Liu Y (2004) Absorption and accumulation of Cd in corn: effects by soil water contents. Acta Ecologica Sinica 24(12):2832–2836Google Scholar
  18. Ibaraki T, Kadoshige K, Murakami M et al (2005) Evaluation of extraction methods for plant-available soil cadmium to wheat by several extraction methods in cadmium-polluted paddy field. Soil Sci Plant Nutr 51(6):893–898CrossRefGoogle Scholar
  19. Kalbitz K, Solinger S, Park JH, Michalzik B, Matzner E (2000) Controls on the dynamics of dissolved organic matter in soils: a review. Soil Sci 165(4):277–304CrossRefGoogle Scholar
  20. Kim HS, Seo BH, Bae JS, Kim WI, Owens G, Kim KR (2016) An integrated approach to safer plant production on metal contaminated soils using species selection and chemical immobilization. Ecotox Environ Saf 131:89–95CrossRefGoogle Scholar
  21. Komarek M, Vanek A, Ettler V (2013) Chemical stabilization of metals and arsenic in contaminated soils using oxidese—a review. Environ Pollut 172:9–22CrossRefGoogle Scholar
  22. Komy ZR, Shaker AM, Heggy SEM, el-Sayed MEA (2014) Kinetic study for copper adsorption onto soil minerals in the absence and presence of humic acid. Chemosphere 99:117–124CrossRefGoogle Scholar
  23. Lee SS, Lim JE, Abd EI-Azeem SAM et al (2013) Heavy metal immobilization in soil near abandoned mines using eggshell waste and rapeseed residue. Environ Sci Pollut Res 20:1719–1726CrossRefGoogle Scholar
  24. Li JR, Xu YM (2015) Immobilization of Cd in a paddy soil using moisture management and amendment. Chemosphere 122:131–136CrossRefGoogle Scholar
  25. Li JR, Xu YM (2017) Use of clay to remediate cadmium contaminated soil under different water management regimes. Ecotox Environ Saf 141:107–112CrossRefGoogle Scholar
  26. Li RY, Zhou ZG, Xie XJ, Li Y, Zhang Y, Xu X (2016b) Effects of dissolved organic matter on uptake and translocation of lead in Brassica chinensis and potential health risk of Pb. Int J Environ Res Public Health 13(7):687CrossRefGoogle Scholar
  27. Li W, Xiong B, Wang S, Deng X, Yin L, Li H (2016a) Regulation effects of water and nitrogen on the source-sink relationship in potato during the tuber bulking stage. PLoS One 11(1):0146877.  https://doi.org/10.1371/journal.pone.0146877 Google Scholar
  28. Liang B, Lehmann J, Solomon D et al (2006) Black carbon increases cation exchange capacity in soils. Soil Sci Soc AmJ 70(5):1719–1730CrossRefGoogle Scholar
  29. Liang XF, Han J, Xu YM, Sun Y, Wang L, Tan X (2014) In situ field-scale remediation of Cd polluted paddy soil using sepiolite and palygorskite. Geoderma 235-236:9–18CrossRefGoogle Scholar
  30. Liang XF, Qin X, Huang QQ, Huang R, Yin X, Cai Y, Wang L, Sun Y, Xu Y (2017) Remediation mechanisms of mercapto-grafted palygorskite for cadmium pollutant in paddy soil. Environ Sci Pollut Res 24:23783–23793CrossRefGoogle Scholar
  31. Liang XF, Xu Y, Xu YM, Wang P, Wang L, Sun Y, Huang Q, Huang R (2016) Two-year stability of immobilization effect of sepiolite on Cd contaminants in paddy soil. Environ Sci Pollut Res 23:12922–12931CrossRefGoogle Scholar
  32. Liu X, Ma Z, Zhao X (2014) Effect of different organic manure on cadmium from of soil and resistance of wheat in cadmium contaminated soil. J Soil Water Conserv 28(3):243–247Google Scholar
  33. Livera J, McLaughlin MJ, Hettiarachchi GM et al (2011) Cadmium solubility in paddy soils: effects of soil oxidation, metal sulfides and competitive ions. Sci Total Environ 409(8):1489–1497CrossRefGoogle Scholar
  34. Lu K, Yang X, Gielen G, Bolan N, Ok YS, Niazi NK, Xu S, Yuan G, Chen X, Zhang X, Liu D, Song Z, Liu X, Wang H (2017) Effect of bamboo and rice straw biochars on the mobility and redistribution of heavy metals (Cd, Cu, Pb and Zn) in contaminated soil. J Environ Manag 186:285–292CrossRefGoogle Scholar
  35. Marschner B, Kalbitz K (2003) Controls of bioavailability and biodegradability of dissolved organic matter in soils. Geoderma 113(3–4):211–235CrossRefGoogle Scholar
  36. Meers E, Laing GD, Unamuno V et al (2007) Comparison of cadmium extractability from soils by commonly used single extraction protocols. Geoderma 141:247–259CrossRefGoogle Scholar
  37. Meharg AA, Norton G, Deacon C, Williams P, Adomako EE, Price A, Zhu Y, Li G, Zhao FJ, McGrath S, Villada A, Sommella A, de Silva PMCS, Brammer H, Dasgupta T, Islam MR (2013) Variation in rice cadmium related to human exposure. Environ Sci Technol 47(11):5613–5618CrossRefGoogle Scholar
  38. Mohamed I, Ahamadou B, Li M, Gong C, Cai P, Liang W, Huang Q (2010) Fractionation of copper and cadmium and their binding with soil organic matter in a contaminated soil amended with organic materials. J Soils Sediments 10(6):973–982CrossRefGoogle Scholar
  39. Mohammad K (2017) A review on the adsorption of heavy metals by clay minerals, with special focus on the past decade. Chem Eng J 308:438–462CrossRefGoogle Scholar
  40. Park JH, Choppala GK, Bolan NS, Chung JW, Chuasavathi T (2011) Biochar reduces the bioavailability and phytotoxicity of heavy metals. Plant and Soil 348(1-2):439-451Google Scholar
  41. Peijnenburg WJGM, Zablotskaja M, Vijver MG (2007) Monitoring metals interrestrial environments within a bioavailability framework and a focus on soil extraction. Ecotox Environ Saf 67:163–179CrossRefGoogle Scholar
  42. Ren J, Fan W, Wang X et al (2016) Influences of size fractionated humic acids on arsenite and arsenate complexation and toxicity to Daphnia magna. Water Res 108:68–77CrossRefGoogle Scholar
  43. Richard C, Guyot G, Trubetskaya O, Trubetskoj O, Grigatti M, Cavani L (2009) Fluorescence analysis of humic-like substances extracted from composts: influence of composting time and fractionation. Environ Chem Letter 7(1):61–65CrossRefGoogle Scholar
  44. Römkens PFAM, Guo HY, Chu CL et al (2009) Characterization of soil heavy metal pools in paddy fields in Taiwan: chemical extraction and solid-solution partitioning. J Soils Sediments 9(3):216–228CrossRefGoogle Scholar
  45. Salati S, Quadri G, Tambone F, Adani F (2010) Fresh organic matter of municipal solid waste enhances phytoextraction of heavy metals from contaminated soil. Environ Pollut 158(5):1899–1906CrossRefGoogle Scholar
  46. Sánchez-Marín P, Santos-Echeandía J, Nieto-Cid M et al (2010) Effect of dissolved organic matter (DOM) of contrasting originson Cu and Pb speciation and toxicity to Paracentrotus lividus larvae. Aquat Toxicol 96(2):832–835CrossRefGoogle Scholar
  47. Shirvani M, Sherkat Z, Khalili B et al (2015) Sorption of Pb(II) on palygorskite and sepiolite in the presence of amino acids: equilibria and kinetics. Geoderma 249:21–27CrossRefGoogle Scholar
  48. Spaccini R, Baiano S, Gigliotti G, Piccolo A (2008) Molecular characterization of a compost and its water-soluble fractions. J Agric Food Chem 56(3):1017–1024CrossRefGoogle Scholar
  49. Sun YB, Sun GH, Xu YM, Liu W, Liang X, Wang L (2016) Evaluation of the effectiveness of sepiolite, bentonite, and phosphate amendments on the stabilization remediation of cadmium contaminated soils. J Environ Manag 166:204–210CrossRefGoogle Scholar
  50. Sun YB, Sun GH, Xu YM, Wang L, Liang X, Lin D (2013) Assessment of sepiolite for immobilization of cadmium-contaminated soils. Geoderma 193-194:149–155CrossRefGoogle Scholar
  51. Sun YB, Wang RL, Li Y, Xu Y, Wang L, Liang X, Liu W (2015) In situ immobilization remediation of cadmium in artificially contaminated soil: a chemical and ecotoxicological evaluation. Chem Ecol 31:594–606CrossRefGoogle Scholar
  52. Sun Y, Xu Y, Xu Y et al (2017) Reliability and stability of immobilization remediation of Cd polluted soils using sepiolite under pot and field trials. Environ Pollut 208:739–746CrossRefGoogle Scholar
  53. Tai Y, Li Z, McBride MB (2016) Natural attenuation of toxic metal phytoavailability in 35-year-old sewage sludge-amended soil. Environ Monit Assess 188:241CrossRefGoogle Scholar
  54. Tan WN, Li ZA, Qiu J et al (2011) Lime and phosphate could reduce cadmium uptake by five vegetables commonly grown in South China. Pedosphere 21:223–229CrossRefGoogle Scholar
  55. Wang G, Su MY, Chen YH, Lin FF, Luo D, Gao SF (2006) Transfer characteristics of cadmium and lead from soil to the edible parts of six vegetable species in southeastern China. Environ Pollut 144:127–135CrossRefGoogle Scholar
  56. Wang Q, Chen L, He LY, Sheng XF (2016) Increased biomass and reduced heavy metal accumulation of edible tissues of vegetable crops in the presence of plant growth-promoting Neorhizobium huautlense T1-17 and biochar. Agric Ecosyst Environ 228:9–18CrossRefGoogle Scholar
  57. Xiao QQ, Wong MH, Huang L, Ye Z (2015) Effects of cultivars and water management on cadmium accumulation in water spinach (Ipomoea aquatica Forsk.). Plant Soil 391:33–49CrossRefGoogle Scholar
  58. Xu YM, Liang XF, Sun GH et al (2010) Effects of acid and heating treatments on the structure of sepiolite and its adsorption of lead and cadmium. Environ Sci 31(6):1560–1567Google Scholar
  59. Yang ZB, Liu LX, Lv YF, Cheng Z, Xu X, Xian J, Zhu X, Yang Y (2018) Metal availability, soil nutrient, and enzyme activity in response to application of organic amendments in Cd-contaminated soil. Environ Sci Pollut Res 25:2425–2435CrossRefGoogle Scholar
  60. Ye XX, Li HY, Zhang LG, Chai R, Tu R, Gao H (2018) Amendment damages the function of continuous flooding in decreasing Cd and Pb uptake by rice in acid paddy soil. Ecotox Environ Saf 147:708–714CrossRefGoogle Scholar
  61. Yin XL, Xu YM, Huang R, Huang Q, Xie Z, Cai Y, Liang X (2017) Remediation mechanisms for Cd-contaminated soil using natural sepiolite at the field scale. Environ Sci Process Impact 19:1563–1570CrossRefGoogle Scholar
  62. Zhang P (2016) Effects of amendments and water conditions on the chemical speciation of Cd and Pb in contaminated paddy soil in a mining area. Soil Sediment Contam 20(13)Google Scholar
  63. Zhou T, Wu LH, Luo YM, Christie P (2018) Effects of organic matter fraction and compositional changes on distribution of cadmium and zinc in long-term polluted paddy soils. Environ Pollut 232:514–522CrossRefGoogle Scholar
  64. Zhou WJ, Ren LW, Zhu LZ (2017) Reducement of cadmium adsorption on clay minerals by the presence of dissolved organic matter from animal manure. Environ Pollut 223:247–254CrossRefGoogle Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  • Yiyun Liu
    • 1
    • 2
  • Yingming Xu
    • 1
    • 2
    Email author
  • Xu Qin
    • 1
    • 2
  • Lijie Zhao
    • 1
    • 2
  • Qingqing Huang
    • 1
    • 2
  • Lin Wang
    • 1
    • 2
  1. 1.Innovation Team of Remediation for Heavy Metal Contaminated Farmlands, Agro-Environmental Protection InstituteMinistry of AgricultureTianjinPeople’s Republic of China
  2. 2.Key Laboratory of Original Environmental Pollution Control, Ministry of Agriculture, Tianjin Key Laboratory of Agro-Environment and Agro-Product SafetyTianjinPeople’s Republic of China

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