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Differential response of biochar derived from rice-residue waste on phosphorus availability in soils with dissimilar pH

  • S. Mukherjee
  • M. S. MaviEmail author
  • J. Singh
Original Paper
  • 28 Downloads

Abstract

Although use of biochar as an amendment for soil C accretion has received immense prominence, its role on alleviating crop P demand remains largely contentious. Therefore, an incubation study for 60 days was conducted to examine the impact of biochar derived from rice-residue waste and Inorganic-P on phosphorous availability in soils with dissimilar pH (acid, neutral and alkali soil). The experimental soils were treated with 0, 20 g kg−1 (w/w) rice-residue biochar with three rates of Inorganic-P (KH2PO4) (0, 25, 50 mg kg−1). Application of rice-residue biochar alone or in combination with Inorganic-P in the experimental soils resulted in significant increase in P pools possibly due to greater available P content in biochar itself; biochar impelled decrease in soil P sorption capacity and or; biochar-facilitated release of soil organic matter bound P. Among the Inorganic-P fractions, content of Fe-P and Al-P was greater in acid soil, whereas Ca-P content was higher in neutral or alkali soils, irrespective of biochar and Inorganic-P treatments. Furthermore, ability of rice-residue biochar to decrease phospho-monoesterase activity in the experimental soils was indicative of its significance to act as a long-term source of phosphorous in soil. Therefore, amendment of soil with biochar can be used as an important strategy for sustainable management of surplus rice-residue and fulfilling phosphorous demand in differential pH soils of Indo-Gangetic plains.

Keywords

Biochar Inorganic-P fertilizer Phosphorous fractions Phosphorous sorption Rice-residue Soil pH 

Notes

Acknowledgements

We thank Indian Council of Agricultural Research for providing fellowship to the first author (SM). This manuscript is part of first author’s research thesis submitted for fulfillment of requirement of his degree programme. We thank Ms. Jaskiran for editing the manuscript, Manpreet, Tony for help in preparation of biochar and soil sampling.

References

  1. Alexander TG, Robertson JA (1968) Ascorbic acid as a reductant for total phosphorus determination in soils. Can J Soil Sci 48:217–218CrossRefGoogle Scholar
  2. Ameloot N, Steven SS, Sean DC, Case SDC, Alberti G, McNamara NP, Zavalloni C, Vervisch B, Vedove GD, Neve SD (2014) C mineralization and microbial activity in four biochar field experiments several years after incorporation. Soil Biol Biochem 78:195–203CrossRefGoogle Scholar
  3. AOAC (2000) Official methods of analysis. Association of Official Analytical Chemist, WashingtonGoogle Scholar
  4. Brady NC, Weil RR (2008) Soil phosphorous and potassium, 13th edn. The Nature and Properties of Soils, Washington, pp 595–636Google Scholar
  5. Chen BL, Chen ZM, Lv SF (2011) A novel magnetic biochar efficiently sorbs organic pollutants and phosphate. Bioresour Technol 102:716–723CrossRefGoogle Scholar
  6. Chintala R, Schumacher TE, McDonald LM, Clay DE, Malo DD, Papiernik SK, Clay SA, Julson JL (2014) Phosphorus sorption and availability from biochars and soil/biochar mixtures. CLEAN Soil Air Water 42:626–634CrossRefGoogle Scholar
  7. Chirone R, Salatino P, Seala F (2000) The relevance of attrition to the fate of ashes during fluidizes-bed combustion of a biomass. Proc Combust Inst 28:2279–2285CrossRefGoogle Scholar
  8. Choudhary OP, Mavi MS (2019) Management of sodic waters in agriculture. In: Dagar JC, Yadav RK, Sharma PC (eds) Research developments in saline agriculture. Springer, Singapore, pp 785–813CrossRefGoogle Scholar
  9. Cordell D, Drangert JO, White S (2009) The story of phosphorus: global food security and food for thought. Glob Environ Change 19:292–305CrossRefGoogle Scholar
  10. Cui HJ, Fu ML, Ci E (2011) Enhancing phosphorus availability in phosphorus-fertilized zones by reducing phosphate adsorbed on ferrihydrate using rice straw-derived biochar. J Soils Sedim 11(7):1135–1141CrossRefGoogle Scholar
  11. Deluca TH, Gundale MJ, MacKenzie MD, Jones DL (2015) Biochar effects on soil nutrient transformations. In: Lehman J, Joseph S (eds) Biochar for environmental management: science, technology and implementation. Routledge, New York, pp 421–454Google Scholar
  12. Heckenmuller M, Narita D, Klepper G (2014) Global availability of phosphorus and its implications for global food supply: an economic overview. Kiel Institute for the World Economy, KielGoogle Scholar
  13. Hiloidhari M, Das D, Baruah DC (2014) Bioenergy potential from crop biomass in India. Renew Sustain Energy Rev 32:504–512CrossRefGoogle Scholar
  14. Jackson ML (1973) Soil chemical analysis—advanced course, 2nd edn. A manual of methods useful for instructions and research in soil chemistry, physical chemistry, soil fertility and soil genesis, MadisonGoogle Scholar
  15. Jiang J, Yuan M, Xu R, Bish DL (2015) Mobilization of phosphate in variable-charge soils amended with biochars derived from crop straws. Soil Tillage Res 146:139–147CrossRefGoogle Scholar
  16. Kuo S (1996) Phosphorus. In: Sparks DL (ed) Methods of soil analysis, part 3-chemical methods. Agron Monog 9, ASA and SSSA, Madison, pp 869–920Google Scholar
  17. Laird DA, Fleming PD, Karlen DL, Wang B, Horton R (2010) Biochar impact on nutrient leaching from a Midwestern agricultural soil. Geodarma 158:436–442CrossRefGoogle Scholar
  18. Lehmann J, Rilling MC, Thies J, Masiello CA, Hockaday WC, Crowley D (2011) Biochar effects on soil biota—a review. Soil Biol Biochem 43:1812–1836CrossRefGoogle Scholar
  19. Liang Y, Cao X, Zhao L, Xu X, Haris W (2014) Phosphorous release from dairy manure, the manure-derived biochar and their amended soil: effects of phosphorous nature and soil property. J Environ Qual 43:1504–1509CrossRefGoogle Scholar
  20. Lohan SK, Jat HS, Yadav AK, Sidhu HS, Jat ML, Choudhary M, Peter JK, Sharma PC (2018) Burning issues of paddy residue management in north-west states of India. Renewal Sustain Energy Rev 81:693–703CrossRefGoogle Scholar
  21. Makoto K, Shibata H, Kim YS, Satomura T, Takagi K, Nomura M, Satoh F, Koike T (2012) Contribution of charcoal to short-term nutrient dynamics after surface fire in the humus layer of a dwarf bamboo-dominated forest. Biol Fertil Soils 48:569–577CrossRefGoogle Scholar
  22. Mavi MS, Marschner P (2013) Drying and wetting in saline and saline-sodic soils effects on microbial activity, biomass and dissolved organic carbon. Plant Soil 355:51–62CrossRefGoogle Scholar
  23. Mavi MS, Singh G, Singh BP, Sekhon BS, Choudhary OP, Sagi S, Berry R (2018) Interactive effects of rice-residue biochar and N-fertilizer on soil functions and crop biomass in contrasting soils. J Soil Sci Plant Nutr 18:41–59Google Scholar
  24. Meena JR, Umakant KB, Chakrabarti D, Sharma AR (2015) Tillage and residue management effect on soil properties, crop performance and energy relation in green gram (Vignaradiata L.) under maize-based cropping systems. Soil Water Conserv Res 3:261–272CrossRefGoogle Scholar
  25. Mukherjee S, Mavi MS, Singh J, Singh BP (2019) Rice-residue biochar influences phosphorus availability in differently P status soils. Arch Agron Soil Sci.  https://doi.org/10.1080/03650340.2019.1639153 CrossRefGoogle Scholar
  26. Murphy J, Riley JP (1962) A modified single solution method for the determination of phosphate in natural waters. Anal Chim Acta 27:31–36CrossRefGoogle Scholar
  27. Novak JM, Lima I, Steiner C, Das KC, Busscher WJ, Schomberg W (2009) Characterization of designer biochar produced at different temperatures and their effects on a loamy sand. Ann Environ Sci 3:195–206Google Scholar
  28. Olsen SR, Cole CV, Waanable FS, Dean LA (1954) Estimation of olsen-Phosphorus by extraction with sodium bicarbonate. US Dep Agric 939:21–32Google Scholar
  29. Opala PA, Okalcbo JR, Othieno CO (2012) Effects of organic and inorganic materials on soil acidity and phosphorus availability in a soil incubation study. ISRN Agron.  https://doi.org/10.5402/2012/597216 CrossRefGoogle Scholar
  30. PierZynski GM, McDowell RW, Sims JT (2005) Chemistry, cycling and potential movement of inorganic phosphorus in soils. In: Sims JT, Sharpley AN (eds) Phosphorus: agriculture and the environment. Agron Monog 46, Madison, pp 53–86Google Scholar
  31. Price G (2006) Australian soil fertility manual, 3rd edn. CSIRO, CollingwoodGoogle Scholar
  32. Qian TT, Zhang XS, Hu JY, Jiang H (2013) Effects of environmental conditions on the release of phosphorus from biochar. Chemosphere 93:2069–2075CrossRefGoogle Scholar
  33. Richards LA (1954) Diagnosis and improvement of saline and alkali soils. Soil Sci 78:7–33CrossRefGoogle Scholar
  34. Sarker JR, Singh BP, Cowie AL, Fang Y, Collins D, Dougherty WJ (2018) Carbon and nutrient mineralisation dynamics in aggregate-size classes from different tillage systems after input of canola and wheat residues. Soil Biol Biochem 116:22–38CrossRefGoogle Scholar
  35. Singh BP, Cowie AL (2014) Long-term influence of biochar on native organic carbon mineralization in a low-carbon clayey soil. Sci Res 4:3687Google Scholar
  36. Singh Y, Sidhu HS (2014) Management of cereal crop residues for sustainable rice–wheat production system in the Indo-Gangetic Plains of India. Proc Indian Natl Sci Acad 80:95–114CrossRefGoogle Scholar
  37. Steiner C, Teixeira WG, Lehmann J, Nehls T, Vasconcelos de Macedo JL, Blum WEH, Zech W (2007) Long term effects of manure, charcoal and mineral mfertilization on crop production and fertility on a highly weathered Central Amazonian Upland soil. Plant Soil 291:275–290CrossRefGoogle Scholar
  38. Tabatabai MA (1982) Soil enzymes. In: Page AL, Miller RH, Keeney DR (eds) Methods of soil analysis, part 2, chemical and microbiological properties. American Society of Agronomy, Madison, pp 903–947Google Scholar
  39. Tan ZX, Lagerkvist A (2011) Phosphorus recovery from the biomass ash: a review. Renew Sustain Energy Rev 15:3588–3602CrossRefGoogle Scholar
  40. Vance ED, Brookes PC, Jenkinson DS (1987) An extraction method for measuring soil microbial biomass C. Soil Biol Biochem 19:703–707CrossRefGoogle Scholar
  41. Wang T, Arbestain MC, Hedley M, Bishop P (2012) Predicting phosphorus bioavailability from high-ash biochars. Plant Soil 357:173–187CrossRefGoogle Scholar
  42. Xu G, Sun J, Shao H, Chang X (2014) Biochar had effects on phosphorus sorption and desorption in three soils with differing acidity. Ecol Eng 60:54–60CrossRefGoogle Scholar
  43. Xu G, Shao H, Zhang Y, Junna S (2018) Nonadditive effects of biochar amendments on soil phosphorus fractions in two contrasting soils. Land Degrad Dev 29:1–8CrossRefGoogle Scholar
  44. Yuan JH, Xu RK, Qian W, Wang RH (2011) Comparison of the ameliorating effects on an acidic ultisol between four crop straws and their biochars. J Soils Sedim 11:741–750CrossRefGoogle Scholar
  45. Zhai L, CaiJi Z, Liu J, Wang H, Ren T, Gai X, Xi B, Liu H (2014) Short-term effects of maize residue biochar on phosphorus availability in two soils with different phosphorus sorption capacities. Biol Fertil Soils 51(1):113–122CrossRefGoogle Scholar
  46. Zhang L, Buchet R, Azzar G (2004) Phosphate binding in the active site of alkaline phosphatase activity and the interactions of 2-nitrosoacetophenone with alkaline phosphates induced small structural changes. Biophys J 86:3873–3881CrossRefGoogle Scholar
  47. Zhao XR, Dan LI, Kong J, Lin QM (2014) Does biochar addition influence the change points of soil phosphorus leaching. J Integr Agric 13:499–506CrossRefGoogle Scholar

Copyright information

© Islamic Azad University (IAU) 2019

Authors and Affiliations

  1. 1.Department of Soil SciencePunjab Agricultural UniversityLudhianaIndia

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