Browse > Article
http://dx.doi.org/10.15681/KSWE.2019.35.3.224

Environmental Fate Tracking of Manure-borne NH3-N in Paddy Field Based on a Fugacity Model  

Kim, Mi-Sug (Dept. of Environmental Engineering, Mokpo National University)
Kwak, Dong-Heui (Center for Jeongeup Academy-Industry Cooperation, Dept. of Physically Active Material Science, Chonbuk National University)
Publication Information
Journal of Korean Society on Water Environment / v.35, no.3, 2019 , pp. 224-233 More about this Journal
Abstract
Nitrogen components in liquid manure can reduce safety and quality of environment harmfully. To minimize the environmental risks of manure, understanding fate of manure in environment is necessary. This study aimed at investigating applicability of a simplified Level III fugacity model for simulating $NH_3-N$ component to analyze environmental fate and transport of $NH_3-N$ in liquid manure and to provide basis for improving management of N in the liquid manure system and for minimizing the environmental impacts of N. The model simulation conducted for four environmental compartments (air, water, soil, and rice plants) during rice-cropping to trace $NH_3-N$ component and provided applicability of the Level III fugacity model in studying the environmental fate of $NH_3-N$ in manure. Most of $NH_3-N$ was found in water body and in rice plants depending upon the physicochemical properties and proper removal processes. For more precise model results, the model is needed to modify with the detailed removal processes in each compartment and to collect proper and accurate information for input parameters. Further study should be about simulations of various N-typed fertilizers to compare with the liquid manure based on a modified and relatively simplified Level III fugacity model.
Keywords
Ammonium-Nitrogen; Fertilizer; Fugacity; Liquid manure; Livestock excretions;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Batiha, M. A., Kadhum, A. A. H., Mohamad, A. B., Takriff, M. S., Fisal, Z., Daud, W. R. W., and Batiha, M. M. (2008). MAM-an aquivalence-based dynamic mass balance model for the fate of non-volatile organic chemicals in the agricultural environment, American Journal of Engineering and Applied Sciences, 1(4), 252-259.   DOI
2 Budavari, S., O'Neil, M. J., Smith, A., Heckelman, P. E., and Kinneary, J. F. (Eds). (1996). The Merck Index, 12th ed, Merck & Co., Inc, Whitehouse Station, NJ.
3 Calderon, F. J., McCarty, G. W., Van Kessel, J. A. S., and Reeves, J. B. (2004). Carbon and nitrogen dynamics during incubation of manured soil, Soil Science Society of America Journal, 68, 1592-1599.   DOI
4 Chowdary, V. M., Rao, N. H., and Sarma, P. B. S. (2004). A Coupled soil water and nitrogen balance model for flooded rice fields in India, Agriculture, Ecosystems and Environment, 103, 425-441.   DOI
5 Contreras, W. A., Ginestar, D., Paraiba, L. C., and Bru, R. (2008). Modelling the pesticide concentration in a rice field by a level IV fugacity model coupled with a dispersion- advection equation, Computers and Mathematics with Applications, 56, 657-669.   DOI
6 Cousins, I. T. and Mackay, D. (2000). Transport parameters and mass balance equations for vegetation in Level III fugacity models, Internal report published on the website of the Canadian Environmental Modeling Centre. http://www.trentu.ca/academic/aminss/envmodel/CEMC200001.pdf
7 Cousins, I. T. and Mackay, D. (2001). Strategies for including vegetation compartments in multimedia models, Chemosphere, 44, 643-654.   DOI
8 Dunn, S. M., Vinten, A. J. A., Lilly, A., DeGroote, J., Sutton, M. A., and McGechan, M. (2004). Nitrogen risk assessment model for Scotland: I. Nitrogen leaching, Hydrology and Earth System Sciences, 8, 191-204.   DOI
9 Csiszar, S. A., Gandhi, N., Alexy, R., Benny, D. T., Struger, J., Marvin, C., and Diamond, M. L. (2011). Aquivalence revisited-New model formulation and application to assess environmental fate of ionic pharmaceuticals in Hamilton harbor, Lake Ontario, Environment International, 37, 821-828.   DOI
10 Daubert, T. E. and Danner, R. P. (1989). Physical and thermodynamic properties of pure chemicals: Data compilation, Taylor & Francis: Washington, DC.
11 Gandhi, N., Bhavsar, S. P., Diamond, M. L., Kuwabara, J. S., Marvin-Dipasquale, M., and Krabbenhoft, D. P. (2007). Development of a mercury speciation, fate, and biotic uptake (BIOTRANSPEC) model: application to Lahontan reservoir (Nevada, USA), Environmental Toxicology and Chemistry, 26(11), 2260-2273.   DOI
12 Hu, Y., Wang, D. Z., Zhang, C., Wang, Z. S., Chen, M. H., and Li, Y. (2013). An interval steady-state multimedia aquivalence (ISMA) model of the transport and fate of chloridion in a surface flow constructed wetland system treating oil field wastewater in China, Ecological Engineering, 51, 161-168.   DOI
13 Hubbard, R., Sheridan, J. M., Lowrance, R., Bosch, D. D., and Vellidis, G. (2004). Fate of nitrogen from agriculture in the southeastern Coastal Plain, Journal of Soil and Water Conservation, 59, 72-86.
14 Kim, J., Kim, B., Shin, M., Kim, J. K., Jung, S., Lee, Y., and Park, J. H. (2009). The distribution of nitrogen and the decomposition rate of organic nitrogen in the Youngsan River and the Sumjin River, Korea, Journal of Korean Society on Water Environment, 25, 135-143.
15 Mackay, D., Sang, S., Vlahos, P., Gobas, F., Diamond, M., and Dolan, D. (1994). A rate constant model of chemical dynamics in a Lake ecosystem: PCBs in lake Ontario, Journal of Great Lakes Research, 20(4), 625-642.   DOI
16 Larcher, W. (1995). Physiological Plant Ecology, 3rd ed., Springer, Berlin, Germany.
17 LeBlanc, J. R., Madhavan, S., and Porter, R. E. (1978). Ammonia. In Kirk-Othmerencyclopedia of chemical technology. 3rd, ed., Grayson, M., D. (Eds), John Wiley & Sons, Inc.: New York, pp. 470-516.
18 MacKay, D. (1991). Multimedia environmental models: The fugacity approach, Lewis Publishers, Chelsea.
19 U.S. Department of Health and Human Services (USDHHS). (2004). Toxicological profile for ammonia, Public Health Service Agency for Toxic Substances and Disease Registry, Washington DC. http://www.atsdr.cdc.gov/toxprofiles/tp126.pdf
20 Voltolini, J., Althoff, D. A., and Back, A. J., (2002). Agua de irrigacao para a cultura do arrozirrigado no Sistemapre-germinado, In: Arrozirrigado: Sistema pre-germinado, EPAGRI, Florianopolis, 101-112 [in Portuguese].
21 Weast, R. C., Astle, M. J., and Beyer, W. H. (Eds). (1988). CRC Handbook of chemistry and physics, CRC Press, Inc., Boca Raton, Florida.
22 Windholz, M., Budavari, S., Blumetti, R. F., and Otterbein, E. S. (1983). The Merck index, 10thed., Merck & Co., Inc, Rahway, NJ.