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http://dx.doi.org/10.5338/KJEA.2019.38.4.33

Effect of Weathering of Bottom Ash on Mitigation of Green House Gases Emission from Upland Soil  

Heo, Do Young (Department of Life Science and Environmental Biochemistry, College of Natural Resources & Life Science, Pusan National University)
Hong, Chang Oh (Department of Life Science and Environmental Biochemistry, College of Natural Resources & Life Science, Pusan National University)
Publication Information
Korean Journal of Environmental Agriculture / v.38, no.4, 2019 , pp. 245-253 More about this Journal
Abstract
BACKGROUND: Weathering of bottom ash (BA) might induce change of its surface texture and pH and affect physical and chemical properties of soil associated with greenhouse gas emission, when it is applied to the arable soil. This study was conducted to determine effect of weathering of BA in mitigating emission of greenhouse gases from upland soil. METHODS AND RESULTS: In a field experiment, methane (CH4), carbon dioxide (CO2), and nitrous oxide (N2O) emitted from the soil was periodically monitored using closed chamber. Three month-weathered BA and non-weathered BA were applied to an upland soil at the rates of 0, 200 Mg ha-1. Maize (Zea mays L.) was grown from July 1st to Oct 8th in 2018. Both BAs did not affect cumulative CH4 emission. Cumulative CO2 emission were 23.1, 19.8, and 18.8 Mg/ha/100days and cumulative N2O emission were 35.8, 20.9, and 17.7 kg/ha/100days for the control, non-weathered BA, and weathered BA, respectively. Weathering of BA did not decrease emission of greenhouse gases significantly, compared to the weathered BA in this study. In addition, both BAs did not decrease biomass yields of maize. CONCLUSION: BA might be a good soil amendment to mitigate emissions of CO2 and N2O from arable soil without adverse effect on crop productivity.
Keywords
Bottom ash; Carbon dioxide; Methane; Nitrous oxide;
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Times Cited By KSCI : 3  (Citation Analysis)
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1 Yang, S. S., & Chang, H. L. (1998). Effect of environmental conditions on methane production and emission from paddy soil. Agriculture, Ecosystems & Environment, 69(1), 69-80.   DOI
2 Case, S. D. C., McNamara, N. P., Reay, D. S., & Whitaker, J. (2012). The effect of biochar addition on $N_2O$ and $CO_2$ emissions from a sandy loam soil - The role of soil aeration. Soil Biology and Biochemistry, 51, 125-134.   DOI
3 Chadwick, D. R., Cardenas, L., Misselbrook, T. H., Smith, K. A., Rees, R. M., Watson, C. J., McGepigj, K. L., Williams, J. R., Cloy, J. M., Thorman, R. E., & Dhanoa, M. S. (2014). Optimizing chamber methods for measuring nitrous oxide emissions from plot-based agricultural experiments. European Journal of Soil Science, 65(2), 295-307.   DOI
4 David, M. S., Jeffry, J. F., Peter, G. H., & David, A. Z. (1998). Principles and applications of soil microbiology pp. 498-515, second ed., Pearson Education, USA.
5 Davidson, E. A. (1993). Soil water content and the ratio of nitrous oxide to nitric oxide emitted from soil. In Biogeochemistry of Global Change, pp. 369-386, Springer, Boston, MA.
6 Dobbie, K. E., & Smith, K. A. (2003). Nitrous oxide emission factors for agricultural soils in Great Britain: the impact of soil water-filled pore space and other controlling variables. Global Change Biology, 9(2), 204-218.   DOI
7 Dobbie, K. E., McTaggart, I. P., & Smith, K. A. (1999). Nitrous oxide emissions from intensive agricultural system; Variations between crops and seasons, key driving variables, and mean emission factors. Journal of Geophysical Research Atmospheres, 104(21), 26891-26899.   DOI
8 Hayashi, K., Tokida, T., Kajiura, M., Yanai, Y., & Yano, M., (2015). Cropland soil plant systems control production and consumption of methane and nitrous oxide and their emissions to the atmosphere. Soil Science and Plant Nutrition, 61(1), 2-33.   DOI
9 Jala, S., & Goyal, D. (2006). Fly ash as a soil ameliorant for improving crop production. Bioresource Technology, 97(9), 1136-1147.   DOI
10 Kang, S. W., Seo, D. C., Cheong, Y. H., Park, J. W., Park, J. H., Kang, H. W., Park, K. D., Yong, S. O., & Cho, J. S., (2016). Effect of barley straw biochar application on greenhouse gas emissions from upland soil for Chinese cabbage cultivation in short-term laboratory experiments. Journal of Mountain Science, 13(4), 693-702.   DOI
11 Kim, M. S., Kim, J. H., & Park, K. R., (2010). A Comparison of Methane Production and Community Structure for Methanogen in Rice Paddy Soil and Dry Farm Soils. The Korean Journal of Microbiology, 46(4), 319-325.
12 Kim, S. U., Owens, V., Kim, S. Y., & Hong, C. O. (2017). Effect of different way of bottom ash and compost application on phytoextrqactability of cadmium in contaminated arable soil. Applied Biological Chemistry, 60(4), 353-362.   DOI
13 Kim, S. U., Ruangcharus, C., Kumar, S., Lee, H. H., Park, H. J., Jung, E. S., & Hong, C. O. (2019). Nitrous oxide emission from upland soil amended with different animal manures. Applied Biological Chemistry, 62(1), https://doi.org/10.1186/s13765-019-0409-5.
14 Kim, S. U., Ruangcharus, C., Lee, H. H., Park, H. J., & Hong, C. O. (2019). Effect of Application Rate of Composted Animal Manure on Nitrous Oxide Emission from Upland Soil Supporting for Sweet potato. Korean Journal of Environmental Agriculture, 37(3), 172-178.
15 Kim, Y. G., Lim, W. S., Hong, C. O., & Kim, P. J. (2014). Effect of combined application of bottom ash and compost on heavy metal concentration and enzyme activities in upland soil, Korean Journal of Environmental Agriculture, 33(4), 262-270.   DOI
16 Linn, D. M., & Doran, J. W. (1984). Effect of Water-Filled Pore Space on Carbon Dioxide and Nitrous Oxide Production in Tilled and Nontilled Soils1. Soil Science Society of America Journal, 48(6), 1267-1272.   DOI
17 Kim, Y. T., Kim, H. J., & Jang, C. S. (2012). Characteristics of geopolymer based on recycling resources, Journal of the Crystal Growth and Crystal Technology, 22(3), 152-157.   DOI
18 Kniessa, C. T., Lima, J. C., Prates, P. B., Kuhnen, N. C., & Riella, H. G. (2007). Dilithium dialuminium trisilicate phase obtained using coal bottom ash. Journal of Non-Crystalline Solids, 353(52-54), 4819-4822.   DOI
19 Lee, J. Y., Choi, H. Y., & Yang, J. E. (2011). Physicochemical Effects of Bottom Ash on the Turfgrass Growth Media of Sandy Topsoil in Golf Course. Korean Journal of Turfgrass Science, 24(2), 199-204.
20 Lee, S. I., Kim, G. Y., Choi, E. J., Lee, J. S., & Jung, H. C., (2018). Reduction of Carbon Dioxide and Nitrous Oxide Emissions through Various Biochars Application in the Upland. Journal of the Korea Organic Resource Recycling Association, 26(2), 11-18.   DOI
21 Liu, C. W., & Wu, C. Y. (2004). Evaluation of methane emissions from Taiwanese paddies. Science of The Total Environment, 333(1-3), 195-207.   DOI
22 Liying, S., Lu, L., Zhaozhi, C., Jinyang, W., & Zhengqin, X. (2014). Combined effects of nitrogen deposition and biochar application on emissions of $N_2O$, $CO_2$ and $NH_3$ from agricultural and forest soils. Soil Science and Plant Nutrition, 60(2), 254-265.   DOI
23 Bayuseno, A. P., & Schmahl, W. W. (2010). Understanding the chemical and mineralogical properties of the inorganic portion of MSWI bottom ash. Waste Management, 30(8-9), 1509-1520.   DOI
24 Meima, J. A., & Comans, R. N. (1999). The leaching of trace elements from municipal solid waste incinerator bottom ash at different stages of weathering. Applied Geochemistry, 14(2), 159-171.   DOI
25 Meima, J. A., & Comans, R. N. J. (1997). Geochemical model-ling of weathering reactions in municipal solid waste incinerator bottom ash. Environmental Science & Technology, 31(5), 1269-1276.   DOI
26 Amonette, J. E., Kim, J. B., Russell, C. K., Palumbo, A. V., & Daniels, W. L. (2003). Enhancement of soil carbon sequestration by amendment with fly ash. International Ash Utilization Symposium, Center for Applied Energy Research, University of Kentucky, 1-11.
27 Anand, S. V. (2013). Global environmental issues. Open Access Scientific Reports, 2(2), 1-9.
28 Baciocchi, R., Costa, G., Lategano, E., Marini, C., Polettini, A., Pomi, R., Postorino, P., & Rocca, S. (2010). Accelerated carbonation of different size fractions of bottom ash from RDF incineration. Waste Management, 30(7), 1310-1317.   DOI
29 Baral, K. R., Arthur, E., Olsen, J. E., & Petersen, S. O. (2016). Predicting nitrous oxide emissions from manure properties and soil moisture: an incubation experiment. Soil Biology Biochemistry, 97, 112-120.   DOI
30 Bateman, E. J., & Baggs, E. M. (2005). Contributions of nitrification and denitrification to $N_2O$ emissions from soils at different water-filled pore space. Biology and Fertility of Soils, 41(6), 379-388.   DOI
31 Boone, D. R., Whitman, W. B., & Rouvire, P. (1993). Methanogenesis . pp. 35-80. Springer, USA.
32 Wearing, C., Birch, C. J., & Nairn, J. D. (2008). An Assessment of Tarong Bottom Ash for Use on Agricultural Soils. Development in Chemical Engineering and Mineral Processing, 12(5-6), 531-543.   DOI
33 Nele, A., Steven, S., Case, S. D. C., Giorgio, A., Niall, P. M., Costanza, Z., Bram, V., Gemini, D. V., & Stefan, D. N. (2014). C mineralization and microbial activity in four biochar field experiments several years after incorporation. Soil Biology and Biochemistry, 78, 195-203.   DOI
34 Otte, S., Grobben, N. G., Robertson, L. A., & Jetten, M. S. M. (1996). Nitrous oxide production by Alcaligenes faecalis under transient and dynamic aerobic and anaerobic conditions. Applied and Environmental Microbiology, 62(7), 2421-2426.   DOI
35 Palumbo, A. V., Amonette, J. E., Tarver, J. R., Fagan, L. A., McNeilly, M. S., & Daniels, W. L. (2007). Fly ash characteristics and carbon sequestration potential. Conference: World of Coal Ash - Science, Applications and Sustainability: World of Coal Ash Conference Proceedings, 115-183.
36 Seniunaite, J., & Vasarevicius, S. (2017). Leaching of Copper, Lead and Zinc from Municipal Solid Waste Incineration Bottom Ash. Energy Procedia, 113, 442-449.   DOI
37 Ukwattagea, N. L., Ranjitha, P. G., & Wang, S. H. (2013). Investigation of the potential of coal combustion fly ash for mineral sequestration of $CO_2$ by accelerated carbonation. Energy, 52, 230-236.   DOI
38 Wolf, B. (1944). Determination of nitrate, nitrite, and Ammonium Nitrogen rapid photometric determination in soil and plant extracts. Industrial and Engineering Chemistry, 16(7), 446-447.
39 Rendek, E., Ducom, G., & Germain, P. (2006). Influence of organic matter on municipal solid waste incinerator bottom ash carbonation. Chemosphere, 64(7), 1212-1218.   DOI
40 Park, J. C., Chung, D. Y., Han, G. H. (2012). Effects of Bottom Ash Amendment on Soil Respiration and Microbial Biomass under Anaerobic Conditions. Korean Journal of Soil Science and Fertilizer, 45(2), 260-265.   DOI
41 Rendek, E., Ducom, G., & Germain, P. (2006). Carbon dioxide sequestration in municipal solid waste incinerator (MSWI) bottom ash. Journal of Hazardous Materials, 128(1), 73-79.   DOI
42 Ruser, R., Flessa, H., Russow, R., Schmidt, G., Buegger, F., & Munch, J. C. (2006). Emission of $N_2O$, $N_2$ and $CO_2$ from soil fertilized with nitrate: effect of compaction, soil moisture and rewetting. Soil Biology and Biochemistry, 38(2), 263-274.   DOI
43 Searle, P. L. (1984). The Berthelot or indophenol reaction and its use in the analytical chemistry of nitrogen. A review. Analyst, 109(5), 549-568.   DOI