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Impacts of eucalyptus biochar application on greenhouse gas emission from an upland rice–sugarcane cropping system on sandy soil

Published online by Cambridge University Press:  27 July 2022

Sucharat Butphu  and
Wanwipa Kaewpradit Open the ORCID record for Wanwipa Kaewpradit [Opens in a new window]
Sucharat Butphu
Affiliation:
Department of Agronomy, Faculty of Agriculture, Khon Kaen University, Khon Kaen 40002, Thailand
Wanwipa Kaewpradit*
Affiliation:
Department of Agronomy, Faculty of Agriculture, Khon Kaen University, Khon Kaen 40002, Thailand Northeast Thailand Cane and Sugar Research Center, Khon Kaen University, Khon Kaen 40002, Thailand Nutrition Management for Sustainable Sugarcane Production under Climate Change Project, Khon Kaen University, Khon Kaen 40002, Thailand
*
*Corresponding author: Emails: wanwka@gmail.com; wanwka@kku.ac.th
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Summary

An on-farm field experiment was conducted in northeastern Thailand to assess the effects of different eucalyptus biochar (BC) application rates, in combination with mineral fertilizers, on upland rice and a succeeding crop of sugarcane on sandy soil. Soil mineral N and greenhouse gas emissions were also evaluated. The field experiment consisted of three treatments: no biochar (BC0), 3.1 Mg ha−1 of biochar (BC1), and 6.2 Mg ha−1 of biochar (BC2). All treatments received the same recommended fertilizer rate. Soil mineral N, and emissions of carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O) were monitored after BC application. The results revealed that the BC2 treatment caused lower soil mineral N content than that of the BC0 treatment during the upland rice period. During the sugarcane period, the BC2 treatment induced a greater soil mineral N content than the BC1 treatment but had no significant difference from the BC0 treatment. The BC2 treatment resulted in significantly lower cumulative CH4 and N2O emissions than the BC0 treatment during the upland rice period. In conclusion, we found that the BC2 treatment alleviated the global warming potential from CH4 and N2O emissions throughout the experiment, causing slight changes in soil N availability in the upland rice–sugarcane cropping system.

Keywords

MethaneGlobal warming potentialSoil mineral N
Type
Research Article
Information
Experimental Agriculture , Volume 58 , 2022 , e25
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Copyright
© The Author(s), 2022. Published by Cambridge University Press

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References

Agbede, T.M., Adekiya, A.O., Odoja, A.S., Bayode, L.N., Omotehinse, P.O. and Adepehin, I. (2020). Effects of biochar and poultry manure on soil properties, growth, quality, and yield of cocoyam (Xanthosoma sagittifolium Schott) in degraded tropical sandy soil. Experimental Agriculture 56, 528543.CrossRefGoogle Scholar
Amato, M. and Ladd, J.N. (1988). Assay for microbial biomass based on ninhydrin-reactive nitrogen extracts of fumigated soils. Soil Biology & Biochemistry 20, 107114.CrossRefGoogle Scholar
Baggs, E.M. (2011). Soil microbial sources of nitrous oxide: recent advances in knowledge, emerging challenges and future direction. Current Opinion in Environmental Sustainability 3, 321327.CrossRefGoogle Scholar
Bargmann, I., Martens, R., Rillig, M.C., Kruse, A. and K€ucke, M. (2014). Hydrochar amendment promotes microbial immobilization of mineral nitrogen. Journal of Plant Nutrition and Soil Science 177, 5967.CrossRefGoogle Scholar
Bruun, E.W., Müller-Stöver, D., Ambus, P. and Hauggaard-Nielsen, H. (2011). Application of biochar to soil and N2O emissions: Potential effects of blended fast-pyrolysis biochar with anaerobically digested slurry. European Journal of Soil Science 62, 581589.CrossRefGoogle Scholar
Butnan, S., Deenik, J.L., Toomsan, B., Antal, M.J. and Vityakon, P. (2015). Biochar characteristics and application rates affecting corn growth and properties of soils contrasting in texture and mineralogy. Geoderma. 237–238, 105116 CrossRefGoogle Scholar
Butphu, S., Rasche, F., Cadisch, G. and Kaewpradit, W. (2020). Eucalyptus biochar application enhances Ca uptake of upland rice, soil available P, exchangeable K, yield and N use efficiency of sugarcane in a crop rotation system. Journal of Plant Nutrition and Soil Science 183, 5868.CrossRefGoogle Scholar
de Figueiredo, E.B. and La Scala, N. (2011). Greenhouse gas balance due to the conversion of sugarcane areas from burned to green harvest in Brazil. Agriculture, Ecosystems & Environment 141, 7785.CrossRefGoogle Scholar
Denmead, O.T., Macdonald, B.C.T., Bryant, G., Naylor, T., Wilson, S., Griffith, D.W.T., Wang, W.J., Salter, B., White, I. and Moody, P.W. (2010). Emissions of methane and nitrous oxide from Australian sugarcane soils. Agricultural and Forest Meteorology 150, 748756.CrossRefGoogle Scholar
Gomez, J.D., Denef, K., Stewart, C.E., Zheng, J. and Cotrufo, M.F. (2014). Biochar addition rate influences soil microbial abundance and activity in temperate soils. European Journal of Soil Science 65, 2839.CrossRefGoogle Scholar
Gonzaga, L.C., Carvalho, J.L.N., de Olivaira, B.G., Soares, J.R., Cantarella, H. (2018). Crop residue removal and nitrification inhibitor application as strategies to mitigate N2O emissions in sugarcane fields. Biomass and Bioenergy 119, 206216.CrossRefGoogle Scholar
Graber, E.R., Harel, Y.M., Kolton, M., Cytryn, E., Silber, A., David, D.R., Tsechansky, L., Borenshtein, M. and Elad, Y. (2010). Biochar impact on development and productivity of pepper and tomato grown in fertigated soilless media. Plant and Soil 337, 481496.CrossRefGoogle Scholar
Intergovernmental Panel on Climate Change (IPCC). (2007). Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, UK.Google Scholar
Intergovernmental Panel on Climate Change (IPCC). (2017). Direct global warming potentials. Publications and Data. https://www.ipcc.ch/publications_and_data/ar4/wg1/en/ch2s2-10-2.html.Google Scholar
Ippolito, J.A., Laird, D.A. and Busscher, W.J. (2012). Environmental benefits of biochar. Journal of Environmental Quality 41, 967972.CrossRefGoogle ScholarPubMed
Kaewpradit, W. and Toomsan, B. (2019). Impact of Eucalyptus biochar application to upland rice-sugarcane cropping systems on enzyme activities and nitrous oxide emissions of soil at sugarcane harvest under incubation experiment. Journal of Plant Nutrition 42, 362373.CrossRefGoogle Scholar
Katharina, K., Augustin, J., Hegewald, H., Köbke, S., Dittert, K., Räbiger, T., Quiñones, T.S., Prochnow, A., Hartung, J., Fuß, R., Stichnothe, H., Flessa, H. and Ruser, R. (2021). Nitrification inhibitors reduce N2O emissions induced by application of biogas digestate to oilseed rape. Nutrient Cycling in Agroecosystems 120, 99118.Google Scholar
Koga, N. (2013). Nitrous oxide emissions under a four-year crop rotation system in northern Japan: impacts of reduced tillage, composted cattle manure application and increased plant residue input. Soil Science and Plant Nutrition 59, 5668.CrossRefGoogle Scholar
Lam, W.Y., Chatterton, J., Sim, S., Kulak, M., Beltran, A.M. and Huijbregts, M.A.J. (2021) Estimating greenhouse gas emissions from direct land use change due to crop production in multiple countries. Science of the Total Environment 755, 1433383.CrossRefGoogle ScholarPubMed
Le Mer, J. and Roger, P. (2001). Production, oxidation, emission and consumption of methane by soils: a review. European Journal of Soil Biology 37, 2550.CrossRefGoogle Scholar
Lehmann, J., Rillig, M.C., Thies, J., Masiello, C.A., Hockaday, W.C. and Crowley, D. (2011). Biochar effects on soil biota-A review. Soil Biology & Biochemistry 43, 18121836.CrossRefGoogle Scholar
Lou, L., Wu, B., Wang, L., Lou, L., Xu, X., Hou, J., Xun, B., Hu, B. and Chen, Y. (2011). Sorption and ecotoxicity of pentachlorophenol polluted sediment amended with rice-straw derived biochar. Bioresource Technology 102, 40364041.CrossRefGoogle ScholarPubMed
Luo, L. and Gu, J.D. (2016). Alteration of extracellular enzyme activity and microbial abundance by biochar addition: implication for carbon sequestration in subtropical mangrove sediment. Journal of Environmental Management 182, 2936.CrossRefGoogle ScholarPubMed
Maraseni, T.N., Mushtaq, S. and Maroulis, J. (2009). Greenhouse gas emissions from rice farming inputs: a cross-country assessment. Journal of Agricultural Science, Cambridge 147, 117126.CrossRefGoogle Scholar
Masulili, A., Utomo, W.H. and Syechfani, M.S. (2010). Rice Husk Biochar for Rice Based Cropping System in Acid Soil 1. The Characteristics of Rice Husk Biochar and Its Influence on the Properties of Acid Sulfate Soil and Rice Growth in West Kalimantan, Indonesia. Journal of Agricultural Science 2 3947.CrossRefGoogle Scholar
Nansaior, A., Patanothai, A., Rambo, A.T. and Simaraks, S. (2013). The sustainability of biomass energy acquisition by households in urbanizing communities in Northeast Thailand. Biomass & Bioenergy 52, 113121.CrossRefGoogle Scholar
Paul, E.A. and Clark, F.E. (1989). Soil microbiology and biochemistry. San Diego, California, USA: Academic Press Inc.CrossRefGoogle Scholar
Petter, F.A., Borges de Lima, L., Marimon Junior, B.H., Alves de Morais, L. and Marimon, B.S. (2016). Impact of biochar on nitrous oxide emissions from upland rice. Journal of Environmental Management 169, 2733.CrossRefGoogle ScholarPubMed
Phukongchai, W., Kaewpradit, W. and Rasche, F. (2022). Inoculation of cellulolytic and ligninolytic microorganisms accelerates decomposition of high C/N and cellulose rich sugarcane straw in tropical sandy soils. Applied Soil Ecology 172, 104355.CrossRefGoogle Scholar
Rees, R.M., Baddeley, J.A., Bhogal, A., Ball, B.C., Chadwick, D.R., Macleod, M., Lilly, A., Pappa, V.A., Thorman, R.E., Watson, C.A. and Williams, J.R. (2013). Nitrous oxide mitigation in UK agriculture. Soil Science and Plant Nutrition 59, 315.CrossRefGoogle Scholar
Romero, C.M., Li, C., Owens, J., Ribeiro, G.O., Mcallister, T.A., Okine, E. and Hao, X. (2021). Nutrient cycling and greenhouse gas emissions from soil amended with biochar-manure mixtures. Pedosphere 31, 289302.CrossRefGoogle Scholar
Ruser, R., Flessa, H., Schilling, R., Steindl, H. and Beese, F. (1998). Soil compaction and fertilization effects on nitrous oxide and methane fluxes in potato fields. Soil Science Society of America Journal 62, 15871595.CrossRefGoogle Scholar
Skiba, U. and Smith, K. A. (2000). The control of nitrous oxide emissions from agriculture and natural soils. Chemoshere-Global Change Science 2, 379386.CrossRefGoogle Scholar
Smith, D.M., Inman-bamber, N.G. and Thorburn, P.J. (2005). Growth and function of the sugarcane root system. Field Crops Research 92, 169183.CrossRefGoogle Scholar
Steiner, C., Glaser, B., Teixeira, W.G., Lehmann, J., Blum, W.E.H. and Zech, W. (2008). Nitrogen retention and plant uptake on a highly weathered central Amazonian Ferralsol amended with compost and charcoal. Journal of Plant Nutrition and Soil Science 171, 893899.CrossRefGoogle Scholar
Tecator. (1984). Determination of ammonium nitrogen (ASN 65-32/84) or nitrate nitrogen (ASN 65-31/84) in soil sample extractable by 2 M KCl using flow injection analysis. Application Notes. Tecator, Hoganas, Sweden.Google Scholar
Thawaro, N., Toomsan, B. and Kaewpradit, W. (2017). Sweet sorghum and upland rice: alternative preceding crops to ameliorate ethanol production and soil sustainability within the sugarcane cropping system. Sugar Tech 19, 6471.CrossRefGoogle Scholar
Wang, C., Amom, B., Schulz, K. and Mehdi, B. (2021a). Factors that influence nitrous oxide emissions from agricultural soils as well as their representation in simulation models: a review. Agronomy 11, 770.CrossRefGoogle Scholar
Wang, Y., Li, W., Du, B. and Li, H. (2021b). Effect of biochar applied with plant growth-promoting rhizobacteria (PGPR) on soil microbial community composition and nitrogen utilization in tomato. Pedosphere 31, 872881.CrossRefGoogle Scholar
Weier, K.L. (1998). Sugarcane fields: sources or sinks for greenhouse gas emissions? Australian Journal of Agricultural Research 49, 19.CrossRefGoogle Scholar
Xie, Z., Xu, Y., Liu, G., Liu, Q., Zhu, J., Tu, C., Amonette, J.E., Cadisch, G., Yong, J.W.H. and Hu, S. (2013). Impact of biochar application on nitrogen nutrition of rice, greenhouse-gas emissions and soil organic carbon dynamics in two paddy soils of China. Plant and Soil 370, 527540.CrossRefGoogle Scholar
Xu, T., Lou, L., Lou, L., Cao, R., Duan, D. and Chen, Y. (2012). Effect of bamboo biochar on pentachlorophenol leachability and bioavailability in agricultural soil. Science of the Total Environment 414, 727731.CrossRefGoogle ScholarPubMed
Yao, Y., Gao, B., Zhang, M., Inyang, M. and Zimmerman, A.R. (2012). Effect of biochar amendment on sorption and leaching of nitrate, ammonium, and phosphate in a sandy soil. Chemosphere 89, 14671471.CrossRefGoogle Scholar
Zavalloni, C., Alberti, G., Biasiol, S., DelleVedove, G., Fornasier, F., Liu, J. and Peressotti, A. (2011). Microbial mineralization of biochar and wheat straw mixture in soil: A short-term study. Applied Soil Ecology 50, 4751.CrossRefGoogle Scholar
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