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A preliminary investigation for Cu distribution in paddy soil and rice plants in contaminated paddy fields

  • Seelawut DamrongsiriEmail author
  • Arubol Chotipong
Article

Abstract

The soil sample of a paddy field was found to be contaminated by copper (Cu). The application of wastewater as the nitrogen fertilizer was identified as the cause in this study. The concentration of Cu in soil and rice plants was therefore explored. The paddy soil characteristics indicated a strong anaerobic environment. The Cu concentration in topsoil was 123 ± 24 mg kg−1. The Community Bureau of Reference (BCR)’s fractionation of Cu from high to low was residual fraction (62.1%) > organically bounded and sulfide-bounded fractions (24.2%) > iron oxide and manganese oxide fraction (8.8%) > acid-soluble fractions (4.8%). The concentration of Cu in rice organs was the highest in the roots, followed by the straw, grain, and husk. The correlation of Cu in rice straws with every fractionation of Cu in soil was strong. However, the weak correlation between Cu in rice grains and soil was found. The result of Cu mass balance in the soil–rice cultivation system showed that less than 0.1% of Cu was translocated to rice plant. The average Cu intake through rice grain consumption (621 μg day−1) indicated the Cu supply to human body basic need without any potential negative health impacts to consumer. However, this level of Cu may cause toxicity to rice growth and productivity. Soil replacement may be more appropriate than soil treatment in this study. In addition, agricultural practices should be managed to prevent further contamination and promote more aerobic conditions.

Keywords

Paddy soil Rice Wastewater Copper Fractionation Distribution 

Notes

Funding

This work was supported by the S&T Postgraduate Education and Research Development Office, PERDO [Grant Number: HSM-PJ-CT-18-15].

References

  1. Abedin MJ, Howells C, Meharg AA (2002) Arsenic uptake and accumulation in rice (Oryza sativa L.) irrigated with contaminated water. Plant Soil 240:311–319CrossRefGoogle Scholar
  2. Alloway BJ (1995) The origins of heavy metals in soils. Chapman & Hall, LondonCrossRefGoogle Scholar
  3. Assawadithalerd M, Siangliw M, Tongcumpou C (2014) Effects of organic fertilizer on Cd bioavailability and Cd accumulation in rice grown in contaminated paddy soil. Appl Environ Res 39(2):67–76Google Scholar
  4. Bureau of Rice Research and Development, Rice Department, Ministry of Agriculture and Cooperatives (Thailand) (2009) Fertilization based on soil analysis in rice cultivation. ISBN:978-974-403-624-7Google Scholar
  5. Bureau of Rice Research and Development, Rice Department, Ministry of Agriculture and Cooperatives (Thailand) (2016) Rice knowledge Bank. http://www.ricethailand.go.th/rkb3/title-rice_yield_per_rai.htm
  6. Cao ZH, Hu ZY (2000) Copper contamination in paddy soils irrigated with wastewater. Chemosphere 41:3–6CrossRefGoogle Scholar
  7. Chinoim N, Sinbuathong N (2010) Heavy metal contamination of soils from organic paddy fields in Thailand. In: 19th World Congress of Soil Science, Soil Solutions for a Changing World, pp 119–121Google Scholar
  8. Cooper DC, Morse JW (1998) Extractability of metal sulfide minerals in acidic solutions: application to environmental studies of trace metal contamination within anoxic sediments. Environ Sci Technol 32:1076–1078CrossRefGoogle Scholar
  9. Damrongsiri S (2018) Transformation of heavy metal fractionation under changing environments: a case study of a drainage system in an e-waste dismantling community. Environ Sci Pollut Res 25:11800–11811CrossRefGoogle Scholar
  10. Fageria NK, Santos AB, Cutrim VA (2008) Dry matter and yield of lowland rice genotypes as influence by nitrogen fertilization. J Plant Nutr 31:788–795CrossRefGoogle Scholar
  11. FAO/WHO (1972) Evaluation of certain food additives and of the contaminants mercury, lead and cadmium. FAO Nutrition Meetings Report Series 51, WHO Technical Report Series 505, RomeGoogle Scholar
  12. Fernández-Calviño D, Pérez-Novo C, Nóvoa-Muñoz JC, Arias-Estévez M (2009) Copper fractionation and release from soils devoted to different crops. J Hazard Mater 167:797–802CrossRefGoogle Scholar
  13. Fu QL, Weng N, Fujii M, Zhou DM (2018) Temporal variability in Cu speciation, phytotoxicity, and soil microbial activity of Cu-polluted soils as affected by elevated temperature. Chemosphere 194:285–296CrossRefGoogle Scholar
  14. Hartley W, Dickinson NM (2010) Exposure of an anoxic and contaminated canal sediment: mobility of metal(loid)s. Environ Pollut 158:649–657CrossRefGoogle Scholar
  15. Hensawang S, Chanpiwat P (2017) Health impact assessment of arsenic and cadmium intake via rice consumption in Bangkok, Thailand. Environ Monit Assess 189:599.  https://doi.org/10.1007/s10661-017-6321-8 CrossRefPubMedGoogle Scholar
  16. Hinkle DE, Wiersma W, Jurs SG (2003) Applied statistics for the behavioral sciences, 5th edn. Houghton Mifflin, BostonGoogle Scholar
  17. Hoque MM, Kobata T (2000) Effect of soil compaction on the grain yield of rice (Oryza sativa L.) under water-deficit stress during the reproductive stage. Plant Prod Sci 3(3):316–322CrossRefGoogle Scholar
  18. Huang JH, Hsu SH, Wang SL (2011) Effects of rice straw ash amendment on Cu solubility and distribution in flooded rice paddy soils. J Hazard Mater 186:1801–1807CrossRefGoogle Scholar
  19. Institute of Medicine (2001) Dietary reference intakes for vitamin A, vitamin K, arsenic, boron, chromium, copper, iodine, iron, manganese, molybdenum, nickel, silicon, vanadium, and zinc. The National Academies Press, Washington DCGoogle Scholar
  20. Intorpetch B, Wisawapipat W, Arunlertaree C, Teartisup P (2014) Soil physicochemical status and nutrient management for paddy soils in the lower central plain of Thailand after the flood disaster in 2011. Environ Nat Resour J 12(1):57–67Google Scholar
  21. Kögel-Knabner I, Amelung W, Cao Z, Fiedler S, Frenzel P, Jahn R, Kalbitz K, Kölbl A, Schloter M (2010) Biogeochemistry of paddy soils. Geoderma 157:1–14CrossRefGoogle Scholar
  22. Lee KJ, Feng YY, Choi DH, Lee BW (2016) Lead accumulation and distribution in different rice cultivars. J Crop Sci Biotechnol 19:323–328CrossRefGoogle Scholar
  23. Liu X, Wang H, Zhou J, Hu F, Zhu D, Chen Z, Liu Y (2016) Effect of N fertilization pattern on rice yield, N use efficiency and fertilizer-N fate in the Yangtze River Basin, China. PLOS One 11(11):e0166002.  https://doi.org/10.1371/journal.pone.0166002 CrossRefPubMedPubMedCentralGoogle Scholar
  24. Luh BS (1991) Rice hulls. In: Luh BS (ed) Rice. Springer, BostonCrossRefGoogle Scholar
  25. Luo Y, Jiang X, Wu L, Song J, Wu S, Lu R, Christie P (2003) Accumulation and chemical fractionation of Cu in a paddy soil irrigated with Cu-rich wastewater. Geoderma 115:113–120CrossRefGoogle Scholar
  26. Mitsch WJ, Gosselink JG (2000) Wetlands, 3rd edn. Wiley, New YorkGoogle Scholar
  27. Prakongkep N, Suddhiprakarn A, Kheoruenromne I, Smirk M, Gilkes RJ (2008) The geochemistry of Thai paddy soils. Geoderma 144:310–324CrossRefGoogle Scholar
  28. Qi Y, Huang B, Darilek JL (2014) Effect of drying on heavy metal fraction distribution in rice paddy soil. PLOS One 9(5):e97327.  https://doi.org/10.1371/journal.pone.0097327 CrossRefPubMedPubMedCentralGoogle Scholar
  29. Quintaes KD, Diez-Garcia RW (2015) The importance of minerals in the human diet. In: de la Guardia M (ed) Handbook of mineral elements in food. Wiley, ChichesterGoogle Scholar
  30. Race M, Marotta R, Fabbricino M, Pirozzi F, Andreozzi R, Cortese L, Giudicianni P (2016) Copper and zinc removal from contaminated soils through soil washing process using ethylenediaminedisuccinic acid as a chelating agent: a modeling investigation. J Environ Chem Eng 4:2878–2891CrossRefGoogle Scholar
  31. Tanji KK, Gao S, Scardaci SC, Chow AT (2003) Characterizing redox status of paddy soils with incorporated rice straw. Geoderma 114:333–353CrossRefGoogle Scholar
  32. Tian Z, Li J, He X, Jia X, Yang F, Wang Z (2017) Grain yield, dry weight and phosphorus accumulation and translocation in two rice (Oryza sativa L.) varieties as affected by salt-alkali and phosphorus. Sustainability 9:1461CrossRefGoogle Scholar
  33. Ure AM, Quevauviller Ph, Muntau H, Griepink B (1993) Speciation of heavy metals in soils and sediments. An account of the improvement and harmonization of extraction techniques undertaken under the auspices of the BCR of the commission of the european communities. Int J Environ Anal Chem 51:135–151CrossRefGoogle Scholar
  34. USDA (1996) Method code 6A1. Soil survey laboratory methods manualGoogle Scholar
  35. van Griethuysen C, Gillissen F, Koelmans AA (2002) Measuring acid volatile sulphide in floodplain lake sediments: effect of reaction time, sample size and aeration. Chemosphere 47:395–400CrossRefGoogle Scholar
  36. Xiao L, Guan D, Peart MR, Chen Y, Li Q, Da J (2017a) The influence of bioavailable heavy metals and microbial parameters of soil on the metal accumulation in rice grain. Chemosphere 185:868–878CrossRefGoogle Scholar
  37. Xiao L, Guan D, Peart MR, Chen Y, Li Q (2017b) The respective effects of soil heavy metal fractions by sequential extraction procedure and soil properties on the accumulation of heavy metals in rice grains and brassicas. Environ Sci Pollut Res 24:2558–2571CrossRefGoogle Scholar
  38. Xu J, Yang L, Wang Z, Dong G, Huang J, Wang Y (2006) Toxicity of copper on rice growth and accumulation of copper in rice grain in copper contaminated soil. Chemosphere 62:602–607CrossRefGoogle Scholar
  39. Yan YP, He JY, Zhu C, Cheng C, Pan XB, Sun ZY (2006) Accumulation of copper in brown rice and effect of copper on rice growth and grain yield in different rice cultivars. Chemosphere 65:1690–1696CrossRefGoogle Scholar
  40. Yu TR (1991) Characteristics of soil acidity of paddy soils in relation to rice growth. In: Wright RJ, Baligar VC, Murrmann RP (eds) Plant-soil interactions at low pH, vol 45. Development in Plant and Soil Sciences. Springer, Dordrecht, pp 107–112.  https://doi.org/10.1007/978-94-011-3438-5_12 CrossRefGoogle Scholar
  41. Yu HY, Li FB, Liu CS, Huang W, Liu TX, Yu WM (2016) Iron redox cycling coupled to transformation and immobilization of heavy metals: implications for paddy rice safety in the red soil of south China. Adv Agron 137:279–317CrossRefGoogle Scholar
  42. Zhang J, Li H, Zhou Y, Dou L, Cai L, Mo L, You J (2018) Bioavailability and soil-to-crop transfer of heavy metals in farmland soils: a case study in the Pearl River Delta, South China. Environ Pollut 235:710–719CrossRefGoogle Scholar
  43. Zhao K, Liu X, Zhang W (2011) Spatial dependence and bioavailability of metal fractions in paddy fields on metal concentrations in rice grain at a regional scale. J Soils Sediments 11:1165–1177CrossRefGoogle Scholar
  44. Zhou W, Hesterberg D, Hansen PD, Hutchison KJ, Sayers DE (1999) Stability of copper sulfide in a contaminated soil. J Synchrotron Radiat 6:630–632CrossRefGoogle Scholar

Copyright information

© The International Society of Paddy and Water Environment Engineering 2019

Authors and Affiliations

  1. 1.Environmental Research Institute (ERIC)Chulalongkorn UniversityBangkokThailand
  2. 2.Center of Excellence On Hazardous Substance Management (HSM)Chulalongkorn UniversityBangkokThailand

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