Abstract
Only a few studies have been reported on the stability and heavy metal distribution of soil aggregates after soil treatments to reduce the availability of heavy metals. In this study, apatite (22.3 t ha−1), lime (4.45 t ha−1), and charcoal (66.8 t ha−1) were applied to a heavy metal-contaminated soil for 4 years. The stability and heavy metal distribution of soil aggregates were investigated by dry and wet sieving. No significant change in the dry mean weight diameter was observed in any treatments. Compared with the control, three-amendment treatments significantly increased the wet mean weight diameter, but only charcoal treatment significantly increased the wet aggregate stability. The soil treatments increased the content of soil organic carbon, and the fraction 0.25–2 mm contained the highest content of soil organic carbon. Amendments’ application slightly increased soil total Cu and Cd, but decreased the concentrations of CaCl2 -extractable Cu and Cd except for the fraction <0.053 mm. The fractions >2 and 0.25–2 mm contained the highest concentrations of CaCl2-extractable Cu and Cd, accounted for about 74.5–86.8 % of CaCl2-extractable Cu and Cd in soil. The results indicated that amendments’ application increased the wet soil aggregate stability and decreased the available Cu and Cd. The distribution of available heavy metals in wet soil aggregates was not controlled by soil aggregate stability, but possibly by soil organic carbon.
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Acosta JA, Cano AF, Arocena JM, Debela F, Martínez-Martínez S (2009) Distribution of metals in soil particle size fractions and its implication to risk assessment of playgrounds in Murcia City (Spain). Geoderma 149:101–109
Al-Degs YS, El-Barghouthi MI, Issa AA, Khraisheh MA, Walker GM (2006) Sorption of Zn(II), Pb(II), and Co(II) using natural sorbents: equilibrium and kinetic studies. Water Res 40:2645–2658
Amezketa E (1999) Soil aggregate stability: a review. J Sustain Agric 14:83–151
An SS, Darboux F, Cheng M (2013) Revegetation as an efficient means of increasing soil aggregate stability on the Loess Plateau (China). Geoderma 209:75–85
Arias M, Perez-Novo C, Osorio F, Lopez E, Soto B (2005) Adsorption and desorption of copper and zinc in the surface layer of acid soils. J Colloid Interface Sci 288:21–29
Bach EM, Hofmockel KS (2014) Soil aggregate isolation method affects measures of intra-aggregate extracellular enzyme activity. Soil Biol Biochem 69:54–62
Basta NT, Ryan JA, Chaney RL (2005) Trace element chemistry in residual-treated soil: key concepts and metal bioavailability. J Environ Qual 34:49–63
Bronick CJ, Lal R (2005) Soil structure and management: a review. Geoderma 124:3–22
Cao LX, Liang Y, Wang Y, Lu HZ (2015a) Runoff and soil loss from Pinus massoniana forest in southern China after simulated rainfall. Catena 129:1–8
Cao LX, Zhang YG, Lu HZ, Yuan JQ, Zhu YY, Liang Y (2015b) Grass hedge effects on controlling soil loss from concentrated flow: a case study in the red soil region of China. Soil Tillage Res 148:97–105
Chaplain V, Défossez P, Delarue G, Roger-Estrade J, Dexter AR, Richard G, Tessier D (2011) Impact of lime and mineral fertilizers on mechanical strength for various soil pHs. Geoderma 167:360–368
Chepil WS (1962) A compact rotary sieve and the importance of dry sieving in physical soil analysis. Soil Sci Soc Am J 26:4–6
Cui HB, Zhou J, Si YB, Mao JD, Zhao QG, Fang GD, Liang JN (2014) Immobilization of Cu and Cd in a contaminated soil: one-and four-year field effects. J Soils Sediments 14:1397–1496
Cui HB, Fan YC, Xu L, Zhou J, Zhou DM, Mao JD, Fang GD, Cang L, Zhu ZQ (2016) Sustainability of in situ remediation of Cu- and Cd- contaminated soils with one-time application of amendments in Guixi, China. J Soils Sediments. doi:10.1007/s11368-015-1317-x
Dermont G, Bergeron M, Mercier G, Richer-Lafleche M (2008) Soil washing for metal removal: a review of physical/chemical technologies and field applications. J Hazard Mater 152:1–31
Di Palma L, Ferrantelli MC, Petrucci E, Pitzolu I (2007) Influence of soil organic matter on copper extraction from contaminated soil. Soil Sediment Contam 16:323–335
Egli M, Sartori G, Mirabella A, Giaccai D, Favilli F, Scherrer D, Krebs R, Delbos E (2009) The influence of weathering and organic matter on heavy metals lability in silicatic, alpine soils. Sci Total Environ 408:931–946
Fan JL, Ding WX, Chen ZM, Ziadi N (2012) Thirty-year amendment of horse manure and chemical fertilizer on the availability of micronutrients at the aggregate scale in black soil. Environ Sci Pollut Res 19:2745–2754
Fan JL, Ding WX, Ziadi N (2013) Thirty-year manuring and fertilization effects on heavy metals in black soil and soil aggregates in northeastern China. Commun Soil Sci Plant 44:1224–1241
Giller KE, Witter E, Mcgrath SP (1998) Toxicity of heavy metals to microorganisms and microbial processes in agricultural soils: a review. Soil Biol Biochem 30:1389–1414
Gong C, Ma L, Cheng H, Liu Y, Xu D, Li B, Liu F, Ren Y, Liu Z, Zhao C, Yang Y, Nie H, Lang C (2014) Characterization of the particle size fraction associated heavy metals in tropical arable soils from Hainan Island, China. J Geochem Explor 139:109–114
Hardie M, Clothier B, Bound S, Oliver G, Close D (2014) Does biochar influence soil physical properties and soil water availability? Plant Soil 376:347–361
Jien SH, Wang CS (2013) Effects of biochar on soil properties and erosion potential in a highly weathered soil. Catena 110:225–233
John B, Yamashita T, Ludwig B, Flessa H (2005) Storage of organic carbon in aggregate and density fractions of silty soils under different types of land use. Geoderma 128:63–79
Kuo S, Mcneal BL (1984) Effects of pH and phosphate on cadmium sorption by a hydrous ferric-oxide. Soil Sci Soc Am J 48:1040–1044
Li HB, Han XZ, Wang F, Qiao YF, Xing BS (2007) Impact of soil management on organic carbon content and aggregate stability. Commun Soil Sci Plant 38:1673–1690
Li P, Wang XX, Zhang TL, Zhou DM, He YQ (2009) Distribution and accumulation of copper and cadmium in soil-rice system as affected by soil amendments. Water Air Soil Pollut 196:29–40
Liu ZX, Chen XM, Jing Y, Li QX, Zhang JB, Huang QR (2014) Effects of biochar amendment on rapeseed and sweet potato yields and water stable aggregate in upland red soil. Catena 123:45–51
Ljung K, Selinus O, Otabbong E, Berglund M (2006) Metal and arsenic distribution in soil particle sizes relevant to soil ingestion by children. Appl Geochem 21:1613–1624
Lombi E, Zhao FJ, Wieshammer G, Zhang GY, McGrath SP (2002a) In situ fixation of metals in soils using bauxite residue: biological effects. Environ Pollut 118:445–452
Lombi E, Zhao FJ, Zhang GY, Sun B, Fitz W, Zhang H, McGrath SP (2002b) In situ fixation of metals in soils using bauxite residue: chemical assessment. Environ Pollut 118:435–443
Lu WW, Ding WX, Zhang JH, Li Y, Luo JF, Bolan N, Xie ZB (2014) Biochar suppressed the decomposition of organic carbon in a cultivated sandy loam soil: a negative priming effect. Soil Biol Biochem 76:12–21
Lu YL, Song S, Wang RS, Liu ZY, Meng J, Sweetman AJ, Jenkins A, Ferrier RC, Li H, Luo W, Wang TY (2015) Impacts of soil and water pollution on food safety and health risks in China. Environ Int 77:5–15
Madejon E, Madejon P, Burgos P, de Mora AP, Cabrera F (2009) Trace elements, pH and organic matter evolution in contaminated soils under assisted natural remediation: a 4-year field study. J Hazard Mater 162:931–938
Marques APGC, Rangel AOSS, Castro PML (2011) Remediation of heavy metal contaminated soils: an overview of site remediation techniques. Crit Rev Environ Sci Technol 41:879–914
Marris E (2006) Putting the carbon back: black is the newgreen. Nature 442:624–626
Mikha MM, Rice CW (2004) Tillage and manure effects on soil and aggregate-associated carbon and nitrogen. Soil Sci Soc Am J 68:809–816
Pansu M, Gautheyrou J (2006) Handbook of soil analysis-mineralogical, organic and inorganic methods. Springer, Berlin
Peng X, Yan X, Zhou H, Zhang YZ, Sun H (2015) Assessing the contributions of sesquioxides and soil organic matter to aggregation in an ultisol under long-term fertilization. Soil Tillage Res 146:89–98
Qian J, Shan XQ, Wang ZJ, Tu Q (1996) Distribution and plant availability of heavy metals in different particle-size fractions of soil. Sci Total Environ 187:131–141
Ramos MC (2006) Metals in vineyard soils of the Penedes area (NE Spain) after compost application. J Environ Manag 78:209–215
Rillig MC, Mummey DL (2006) Mycorrhizas and soil structure. New Phytol 171:41–53
Six J, Elliott ET, Paustian K, Doran JW (1998) Aggregation and soil organic matter accumulation in cultivated and native grassland soils. Soil Sci Soc Am J 62:1367–1377
Six J, Bossuyt H, Degryze S, Denef K (2004) A history of research on the link between (micro)aggregates, soil biota, and soil organic matter dynamics. Soil Tillage Res 79:7–31
Sutherland RA (2003) Lead in grain size fractions of road-deposited sediment. Environ Pollut 121:229–237
Tatarko J (2001) Soil aggregation and wind erosion: processes and measurements. Ann Arid Zone 40:251–263
Varrica D, Dongarrà G, Sabatino G, Monna F (2003) Inorganic geochemistry of roadway dust from the metropolitan area of Palermo, Italy. Environ Geol 44:222–230
Walkley A, Black IA (1934) An examination of the Degtjareff method for determining soil organic matter, and a proposed modification of the chromic acid titration method. Soil Sci 37:29–38
Wang XS, Qin Y, Chen YK (2006) Heavy meals in urban roadside soils, part 1: effect of particle size fractions on heavy metals partitioning. Environ Geol 50:1061–1066
Wang SY, Tsai MH, Lo SF, Tsaiet MJ (2008) Effects of manufacturing conditions on the adsorption capacity of heavy metal ions by Makino bamboo charcoal. Bioresour Technol 99:7027–7033
Wang EH, Cruse RM, Chen XW, Daigh A (2012) Effects of moisture condition and freeze/thaw cycles on surface soil aggregate size distribution and stability. Can J Soil Sci 92:529–536
Wuddivira MN, Camps-Roach G (2007) Effects of organic matter and calcium on soil structural stability. Eur J Soil Sci 58:722–727
Xu YP, Schwartz FW, Traina SJ (1994) Sorption of Zn2+ and Cd2+ on hydroxyapatite surfaces. Environ Sci Technol 28:1472–1480
Yang XM, Wander MM (1998) Temporal changes in dry aggregate size and stability: tillage and crop effects on a silty loam Mollisol in Illinois. Soil Tillage Res 49:173–183
Youker RE, Mcguinness JL (1957) A short method of obtaining mean weight-diameter values of aggregate analyses of soils. Soil Sci 83:291–294
Zhang MK, He ZL, Calvert DV, Stoffella PJ, Yang XE, Li YC (2003) Phosphorus and heavy metal attachment and release in sandy soil aggregate fractions. Soil Sci Soc Am J 67:1158–1167
Acknowledgments
This work was financially supported by the National Key Technology Research and Development Program of China (2015BAD05B01), Science and Technology Service Network Initiative of the Chinese Academy of Sciences (KFJ-EW-STS-016), Gan Po “555” Talent Program, the PhD Fund of Anhui University of Science and Technology (11276), the National Key Basic Research Program of China (2013CB934302), and the grants from Key Laboratory of Soil Environment and Pollution Remediation, Institute of Soil Science, Chinese Academy of Sciences. We thank Mr. Qingtang Zhang for the assistance with field work and the anonymous reviewers for their comments and suggestions.
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Cui, H., Ma, K., Fan, Y. et al. Stability and heavy metal distribution of soil aggregates affected by application of apatite, lime, and charcoal. Environ Sci Pollut Res 23, 10808–10817 (2016). https://doi.org/10.1007/s11356-016-6271-7
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DOI: https://doi.org/10.1007/s11356-016-6271-7