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Simulating Ammonia Volatilization from Applications of Different Urea Applied in Rice Field by WNMM  

Park, Ki-Do (Division of Plant Environment, Yeongnam Agricultural Research Institute, NICS, RDA)
Lee, Dong-Wook (Division of Plant Environment, Yeongnam Agricultural Research Institute, NICS, RDA)
Li, Yong (School of Resource Management, Institute of Land and Food Resources, The University of Melbourne)
Chen, Deli (School of Resource Management, Institute of Land and Food Resources, The University of Melbourne)
Park, Chang-Young (Division of Plant Environment, Yeongnam Agricultural Research Institute, NICS, RDA)
Lee, Young-Han (Gyeongsangnamdo Agricultural Research & Extension Services)
Lee, Chang-Hoon (Division of Plant Environment, Yeongnam Agricultural Research Institute, NICS, RDA)
Kang, Ui-Gum (Division of Plant Environment, Yeongnam Agricultural Research Institute, NICS, RDA)
Park, Sung-Tae (Division of Plant Environment, Yeongnam Agricultural Research Institute, NICS, RDA)
Cho, Young-Son (National Institute of Crop Science, RDA)
Publication Information
KOREAN JOURNAL OF CROP SCIENCE / v.53, no.1, 2008 , pp. 8-14 More about this Journal
Abstract
Ammonia ($NH_3$) volatilization from a silty clay loam paddy soil applied with non, straight urea, and coated urea, respectively, under transplanting in Milyang, Korea from 2002 and 2003 was simulated by a Water and Nitrogen Management Model (WNMM). Based on the data from the in-situ measurements, $NH_3$ volatilization during the rice growth was 6.04% and 1.46% of the applied nitrogen (N) from straight urea and coated urea, respectively. The bulk aerodynamic approach in WNMM satisfactorily predicted the difference in $NH_3$ loss during the given rice growing seasons from the two urea fertilizers. $R^2$ for the correlation between the predicted and observed NH3 loss during the calibration year (2002) was 0.53 less than 0.68 of the application year (2003). This difference could be due to the weather condition such as heavy rainfall and temperature during the calibration year.
Keywords
ammonia volatilization; paddy field; coated urea; simulation;
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1 Fenn, L. B. and L. R. Hossner. 1985. Ammonia volatilization from ammoniumor ammonium-forming nitrogen fertilizers. Advances in Soil Science. 1 : 122-169
2 Fillery, I. R. P., J. R. Simpson, and De Datta, S. K. 1984. Influence of field environment and fertilizer management on ammonia loss from flooded rice. Soil Sci. Soc. Am. J. 48 : 914-920   DOI   ScienceOn
3 Hansen, S., H. E. Jensen, N. E. Nielsen, and H. Svendsen. 1990. DAISY: Soil Plant Atmosphere system Model, NPO Rep. A10, 272pp. Natl. Agency for environ. Prot., Copenhagen. http://metsky.kma.go.kr
4 Laville, P., C. Jambert, P. Celler, and Dlemas, R. 1999. Nitrous oxide fluxes from a fertilised maize crop using micrometeorological and chamber methods. Agricultural and forest Metheorology. 96 : 19-38   DOI   ScienceOn
5 Vlek, P. L. G. and E. T. Craswell. 1979. Effect of N source and management on ammonia volatilization losses from floodedrice systems. Soil Sci. Soc. Am. J. 43 : 352-358   DOI
6 Jayaweera, G. R. and D. S. Mikkelsen. 1990. Ammonia volatilization from flooded soil systems: A computer model. I. Theoretical aspects. Soil Sci. Soc. Am. J. 54 : 1447-1455   DOI
7 Whitehead, D. C. and N. Raistrick. 1993. The volatilization of ammonia from cattle urine applied to soils as influenced by soil properties. Plant and Soil. 148 : 43-51   DOI
8 Kim, S. S., M. G. Choi, K. H. Park, S. Y. Lee, S. Y. Cho, and D. S. Cho. 1996. Effect of Band Application of Slow Release Fertilizer on Rice Growth and Yield in Puddledsoil Drill Seeding. Korean Journal of Crop Science. 41.1, pp. 68-76
9 Black, A. S., R. R. Sherlock, K. C. Cameron, N. P. Smith, and K. M. Goh. 1985. Comparison of three field methods for measuring ammonia volatilization from urea granules broad-cast on to pasture. J. Soil Sci. 36 : 271-278   DOI
10 Fillery, I. R. P. and P. L. G. Vlek. 1986. Reappraisal of the significance of ammonia volatilization as an N loss mechanism in flooded rice fields. Fert. Res. 9 : 265-275   DOI
11 Li, Y. 2002. A spatially referenced model for identifying optimal strategies for managing water and fertilizer nitrogen under intensive cropping in the North China Plain. Ph. D thesis. University of Melbourne, Victoria, Australia. 257pp
12 Leuning, R., O. T. Denmead, J. R. Simpson, and Freney, J. R. 1984. Processes of ammonia loss from shallow floodwater. Atmos. Environ. 18 : 1583-1592   DOI
13 Li, C., Frolking, S. and T. A. Frolking. 1992. A model of nitrous oxide evolution from soil driven by rainfall events: 1. Model structure and sensitivity. J. Geophys. Res. 97 (D9) : 9759-9776   DOI
14 Parton, W. J., A. R. Mosier, D. S. Ojima, D. W. Valentine, D. S. Schimel, K. Weier, and A. E. Kulmala. 1996. Generalized model for $N_2$ and $N_2O$ production from nitrification and denitrification. Global Biogeochemical Cycles. 10(3) : 401-412   DOI   ScienceOn
15 Lee, J. H, H. J. Lee, and B. Y. Lee. 1999. Effects of Urease Inhibitor, Nitrification Inhibitor, and Slow-release Fertilizer on Nitrogen Fertilizer Loss in Direct-Seeding Rice. Korean Journal of Crop Science. 44.3. pp. 230-235
16 Sadao, S. and A. T. Gandeza. 1992. Controlled release fertilizers with polyolefin resin coating. Konno Printing Co. Ltd. Japan. 92pp
17 Freney, J. R., R. Leuning, J. R. Simpson, O. T. Denmead, and W. A. Muirhead. 1985. Estimating ammonia volatilization from flooded rice fields by simplified techniques. Soil Sci. 49 : 1049-1054   DOI   ScienceOn
18 Savent, N. K. and S. K. De Datta. 1982. Nitrogen transformations in wetland rice soils. Adv. Agron. 35 : 241-302   DOI
19 Sherlock, R. R., J. R. Freney, P. E. Bacon, and T. J. van der Weerden. 1995. Estimating ammonia volatilization from unsaturated urea fertilized and urine affected soils by an indirect method. Fertilizer Research. 40 : 197-205   DOI
20 Korean meteorological administration web site : http://metsky.kma.go.kr
21 Nommik, H. 1973. The effect of pellet size on the ammonia loss from urea applied to forest soil. Plant and Soil. 39 : 309-318   DOI
22 Williams, J. R. 1995. The EPIC model, in Computer Models of watershed Hydrology. edited by V. P. Singh. Water Resour. Publ., Highlands Ranch, Colo. pp. 909-1000
23 Sommer, S. G. and A. K. Ersboll. 1996. Effect of air flow rate, lime amendments and chemical soil properties on the volatilization of ammonia from fertilizers applied to sandy soils. Boil. Fert. Soils. 21 : 53-60   DOI
24 Li, Y., D. L. Chen, Y. M. Zhang, R. Edis, and H. Ding. 2005. Comparison of three modeling approaches for simulating denitrification and nitrous oxide emission from loam-textured arable soils. Global Biogeochemical Cycles. 19, GB3002, doi : 10.1029/2004GB002392   DOI