Abstract
Introduction of heavy metals in the environment by various anthropogenic activities has become a potential treat to life. Among the heavy metals, cadmium (Cd) shows relatively high soil mobility and has high phyto-mammalian toxicity. Integration of soil remediation and ecosystem services, such as carbon sequestration in soils through organic amendments, may provide an attractive land management option for contaminated sites. The application of biochar in agriculture has recently received much attention globally due to its associated multiple benefits, particularly, long-term carbon storage in soil. However, the application of biochar from softwood crop residue for heavy metal immobilization, as an alternative to direct field application, has not received much attention. Hence, a pot experiment was conducted to study the effect of pigeon pea biochar on cadmium mobility in a soil-plant system in cadmium-spiked sandy loam soil. The biochar was prepared from pigeon pea stalk through a slow pyrolysis method at 300 °C. The experiment was designed with three levels of Cd (0, 5, and 10 mg Cd kg−1 soil) and three levels of biochar (0, 2.5, and 5 g kg−1 soil) using spinach as a test crop. The results indicate that with increasing levels of applied cadmium at 5 and 10 mg kg−1 soil, the dry matter yield (DMY) of spinach leaf decreased by 9.84 and 18.29 %, respectively. However, application of biochar (at 2.5 and 5 g kg−1 soil) significantly increased the dry matter yield of spinach leaf by 5.07 and 15.02 %, respectively, and root by 14.0 and 24.0 %, respectively, over the control. Organic carbon content in the post-harvest soil increased to 34.9 and 60.5 % due to the application of biochar 2.5 and 5 g kg−1 soil, respectively. Further, there was a reduction in the diethylene triamine pentaacetic acid (DTPA)-extractable cadmium in the soil and in transfer coefficient values (soil to plant), as well as its concentrations in spinach leaf and root, indicating that cadmium mobility was decreased due to biochar application. This study shows that pigeon pea biochar has the potential to increase spinach yield and reduce cadmium mobility in contaminated sandy soil.
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References
Amonette, J. E., & Joseph, S. (2009). Characteristics of biochar: microchemical properties. In J. Lehmann & S. Joseph (Eds.), Biochar for environmental management science and technology (pp. 33–52). London: Earthscan.
Asai, H., Samson, B. K., Stephan, H. M., Songyikhangsuthor, K., Homma, K., Kiyono, Y., Inoue, Y., Shiraiwa, T., & Horie, T. (2009). Biochar amendment techniques for upland rice production in Northern Laos 1. Soil physical properties, leaf SPAD and grain yield. Field Crops Research, 111, 81–84.
Beesley, L., Moreno-Jiménez, E., Gómez-Eyles, J. L., Harris, E., Robinson, B., & Sizmur, T. (2011). A review of biochars’ potential role in the remediation, revegetation and restoration of contaminated soils. Environmental Pollution, 159, 3269–3282.
Blackwell, P., Riethmuller, G., & Collins, M. (2009). Biochar application to soil. In J. Lehmann & S. Joseph (Eds.), Biochar for environmental management: science and technology (pp. 207–226). London: Earthscan.
Brendova, K., Tlustos, P., & Szakova, J. (2015). Biochar immobilizes cadmium and zinc and improves phytoextraction potential of willow plants on extremely contaminated soil. Plant, Soil and Environment, 61, 303–308.
Brennan, A., Moreno Jimenez, E., Alburquerque, J. A., Knapp, C. W., & Switzer, C. (2014). Effects of biochar and activated carbon amendment on maize growth and the uptake and measured availability of polycyclic aromatic hydrocarbons (PAHs) and potentially toxic elements (PTEs). Environmental Pollution, 193, 79–87.
Cao, X. D., Ma, L. N., Gao, B., & Harris, W. (2009). Dairy-manure derived biochar effectively sorbs lead and atrazine. Environmental Science and Technology, 43, 3285–3291.
Clarholm, M. (1994). Granulated wood ash and a ‘N-free’ fertilizer to forest soil: effects on P availability. Forest Ecology and Management, 66, 127–136.
Clemente, R., & Bernal, M. P. (2006). Fractionation of heavy metals and distribution of organic carbon in two contaminated soils amended with humic acids. Chemosphere, 64, 1264–1273.
Downie, A., Crosky, A., & Munroe, P. (2009). Physical properties of biochar. In J. Lehmann & S. Joseph (Eds.), Biochar for environmental management: science and technology (pp. 13–32). London: Earthscan.
Fellet, G., Marmiroli, M., & Marchiol, L. (2014). Elements uptake by metal accumulator species grown on mine tailings amended with three types of biochar. Science of the Total Environment, 468–469, 598–608.
Fierer, N., Schimel, J. P., Cates, R. G., & Zou, J. (2001). Influence of balsam poplar tannin fractions on carbon and nitrogen dynamics in Alaskan taiga floodplain soils. Soil Biology and Biochemistry, 33, 1827–1839.
Glaser, B., & Birk, J. J. (2012). State of the scientific knowledge on properties and genesis of Anthropogenic Dark Earths in Central Amazonia (terra preta de Indio). Geochimica et Cosmochimica Acta, 82, 39–51.
Gomez, K. A., & Gomez, A. A. (1984). Statistical procedures for agricultural research. Singapore: Wiley.
Haghiri, F. (1973). Cadmium uptake by plants. Journal of Environmental Quality, 2, 93–96.
Hossain, M. K., Strezo, V., Cha, K. Y., & Nelson, P. F. (2010). Agronomic properties of wastewater sludge biochar and bioavailability of metals in production of cherry tomato (Lycopersicon esculentum). Chemosphere, 78, 1167–1171.
Houben, D., Evrard, L., & Sonnet, P. (2013). Mobility, bioavailability and pH-dependent leaching of cadmium, zinc and lead in a contaminated soil amended with biochar. Chemosphere, 92, 1450–1457.
Kimetu, J. M., Lehmann, J., Ngoze, J., Mugendi, S., Kinyangi, D. N., Riha, J., Verchot, S., Recha, L., & Pell, J. W. (2008). Reversibility of productivity decline with organic matter of differing quality along a degradation gradient. Ecosystems, 45, 123–126.
Krupa, Z., Skorzynska, E., Maksymiec, W., & Baszyński, T. (1987). Effect of cadmium treatment on photosynthetic apparatus and its photochemical activities in greening radish seedlings. Photosynthetica, 21, 156–164.
Kumari, K. G. I. D., Moldrup, P., Paradelo, M., & de Jonge, L. W. (2014). Phenanthrene sorption on biochar-amended soils: application rate, aging and physicochemical properties of soil. Water, Air, and Soil Pollution, 225, 2105.
Kumpiene, J., Lagerkvist, A., & Maurice, C. (2008). Stabilization of As, Cr, Cu, Pb and Zn in soil using amendments–a review. Waste Management, 28, 215–225.
Laird, D. A., Fleming, P., Davis, D. D., Horton, R., Wang, B., & Karlen, D. L. (2010). Impact of biochar amendments on the quality of a typical Midwestern agricultural soil. Geoderma, 158, 443–449.
Lehmann, J. A. (2007). A handful of carbon. Nature, 447, 143–144.
Lehmann, J., Pereira, D. A., Silva, J. R. J., Steiner, C., Nehls, T., Zech, W., & Glaser, B. (2003). Nutrient availability and leaching in an archaeological Anthrosol and a Ferralsol of the Central Amazon basin: fertilizer, manure and charcoal amendments. Plant and Soil, 249, 343–357.
Liang, B., Lehmann, J., Solomon, D., Kinyangi, J., Grossman, J., O’Neill, B., Skjemstad, J. O., Thies, J., Luizao, F. J., Peterson, J., & Neves, E. G. (2006). Black carbon increases cation exchange capacity in soils. Soil Science Society of America Journal, 70, 1719–1730.
Libra, J. A., Ro, K. S., Kammann, C., Funke, A., Berge, N. D., Neubauer, Y., Titirici, M. M., Fühner, C., Bens, O., Kern, J., & Emmerich, K. H. (2011). Hydrothermal carbonization of biomass residuals: a comparative review of the chemistry, processes and applications of wet and dry pyrolysis. Biofuels, 2, 71–106.
Lindsay, W. L., & Norvell, W. A. (1978). Development of DTPA soil test for zinc, iron, manganese and copper. Soil Science Society of America Journal, 42, 421–428.
Lu, H., Zhang, Y. Y., Huang, X., Wang, S., & Qiu, R. (2012). Relative distribution of Pb2+ sorption mechanisms by sludge-derived biochar. Water Resources, 46, 854–862.
Lu, H., Li, Z., Fu, S., Mendez, A., Gasco, G., & Paz-Ferreiro, J. (2014). Can biochar and phytoextractors be jointly used for cadmium remediation? PloS One, 9, e95218.
Lu, H., Li, Z., Fu, S., Mendez, A., Gasco, G., & Paz-Ferreiro, J. (2015a). Effect of biochar in cadmium availability and soil biological activity in an anthrosol following acid rain deposition and aging. Water, Air, and Soil Pollution, 226, 164–175.
Lu, H. P., Li, Z. A., Fu, S., Mendez, A., Gasco, G., & Paz-Ferreiro, J. (2015b). Combining phytoextraction and biochar addition improves soil biochemical properties in a soil polluted with Cd. Chemosphere, 119, 209–216.
Mahmood, S., Finlay, R. D., Fransson, A. M., & Wallander, H. (2003). Effects of hardened wood ash on microbial activity, plant growth and nutrient uptake by ectomycorrhiza spruce seedlings. FEMS Microbiology Ecology, 43, 121–131.
Mendez, A., Paz-Ferreiro, J., Araujo, F., & Gasco, G. (2014). Biochar from pyrolysis of deinking paper sludge and its use in the treatment of a nickel polluted soil. Journal of Analysis Applied Pyrology, 107, 46–52.
Mukherjee, A., Zimmerman, A. R., Hamdan, R., & Cooper, W. T. (2014). Physicochemical changes in pyrogenic organic matter (biochar) after 15 months of field aging. Solid Earth, 5, 693–704.
Mumme, J., Eckervogt, L., Pielert, J., Diakite, M., Rupp, F., & Kern, J. (2011). Hydrothermal carbonization of anaerobically digested maize silage. Bioresource Technology, 102, 9255–9260.
Namgay, T., Singh, B., & Singh, B.P. (2010). Plant availability of arsenic and cadmium as influenced by biochar application to Soil. Proceedings of 19th World Congress of Soil Science, Soil Solutions for a Changing World (Brisbane, Australia,1 – 6 August 2010), pp.78-81.
Nigussie, A., Kissi, E., Misganaw, M., & Ambaw, G. (2012). Effect of biochar application on soil properties and nutrient uptake of lettuces (Lactuca sativa) grown in chromium polluted soils. American-Eurasian Journal of Agricultural and Environmental Sciences, 12(3), 369–376.
Park, J. H., Choppala, G. H., Bolan, N. S., Chung, J. W., & Chuasavathi, T. (2011). Biochar reduces the bioavailability and phytotoxicity of heavy metals. Plant and Soil, 348, 439–451.
Paz-Ferreiro, J., Lu, H., Fu, S., Méndez, A., & Gascó, G. (2014). Use of phytoremediation and biochar to remediate heavy metal polluted soils: a review. Solid Earth, 5, 65–75.
Rondon, M. A., Lehmann, J., Ramirez, J., & Hurtado, M. (2007). Biological nitrogen fixation by common beans (Phaseolus vulgaris L.) increases with bio-char additions. Biology and Fertility of Soils, 43, 699–708.
Solomon, D., Lehmann, J., Kinyangi, J., Amelung, W., Lobe, I., Pell, A., Riha, S., Ngoze, S., Verchot, L., Mbugua, D., Skjemstad, J., & Schafer, T. (2007). Long-term impacts of anthropogenic perturbations on dynamics and speciation of organic carbon in tropical forest and subtropical grassland ecosystems. Global Change Biology, 13, 511–530.
Uchimiya, M., Lima, I. M., Klasson, K. T., Chang, S., Wartelle, L. H., & Rodgers, J. E. (2010). Immobilization of heavy metal ions (CuII, CdII, NiII, and PbII) by broiler litter-derived biochars in water and soil. Journal of Agricultural Food Chemistry, 58, 5538–5544.
Uchimiya, M., Wartelle, L. H., Klasson, K. T., Fortier, C. A., & Lima, I. M. (2011). Influence of pyrolysis temperature on biochar property and function as a heavy metal sorbent in soil. Journal of Agriculture and Food Chemistry, 59, 2501–2510.
Walkley, A., & Black, I. A. (1934). An examination of the Degtijariff method for determining soil organic matter and a proposed modification the chromic acid titration method. Soil Science, 37, 29–38.
Warnock, D. D., Lehmann, J., Kuyper, T. W., & Rillig, M. C. (2007). Mycorrhizal responses to biochar in soil–concepts and mechanisms. Plant and Soil, 300, 9–20.
WHO. (1996). Guidelines for drinking water quality, Second Edition-Volume 2. Health criteria and other supporting information. World Health Organization (WHO) Geneva.
Yamato, M., Okimori, Y., Wibowo, I. F., Anshori, S., & Ogawa, M. (2006). Effects of the application of charred bark of Acacia mangium on the yield of maize, cowpea and peanut, and soil chemical properties in South Sumatra, Indonesia. Soil Science and Plant Nutrition, 52, 489–495.
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The author sincerely thanks Dr. Vidhya Iyer for English language editing during manuscript preparation.
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Coumar, M.V., Parihar, R.S., Dwivedi, A.K. et al. Impact of pigeon pea biochar on cadmium mobility in soil and transfer rate to leafy vegetable spinach. Environ Monit Assess 188, 31 (2016). https://doi.org/10.1007/s10661-015-5028-y
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DOI: https://doi.org/10.1007/s10661-015-5028-y