Journal of Korean Society for Atmospheric Environment (한국대기환경학회지)

Korean Society for Atmospheric Environment (한국대기환경학회)
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The Relevance of Soil N2O Emissions Measured by a Closed Chamber Technique on the Physico-chemical Soil Parameters

Closed chamber를 이용한 토양 N2O 배출량과 주요 토양 인자들과의 상관성

  • 김득수 (군산대학교 토목환경공학부 환경공학전공 대기환경연구실) ;
  • 오진만 (군산대학교 토목환경공학부 환경공학전공 대기환경연구실)
  • Published : 2004.12.01
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Abstract

Nitrous oxide ($N_2$O) has been known as an important trace gas due to the greenhouse gas and the major source of stratospheric oxide of nitrogen (NO). Soil is the major source of $N_2$O in nature. The physicochemical characteristics of soils affect the emission of $N_2$O from soil. These physicochemical parameters are soil moisture, soil temperature, and soil N content. Since these parameters are correlated to the flux of $N_2$O from soil individually and compositely, there still remain many unknowns in the mechanism to produce $N_2$O in soil and the roles of such physicochemical parameters which affect the soil $N_2$O emission. Soil $N_2$O fluxes were measured at different levels in water filled pore space (WFPS), soil temperature and soil N contents from the same amounts of soils which were sampled from agriculturally managed upland field in a depth of ~30 cm at Kunsan. The soil $N_2$O flux measurements were conducted in a laboratory with a closed flux chamber system. The optimum soil moisture and soil temperature were observed at 60% of WFPS and ~13$^{\circ}C$. The soil $N_2$O flux increased as soil N contents increases during the whole experimental hours (up to 48 hours). However, average $N_2$O flux decreased after ~30 hours when organic carbon was mixed with nitrogen in the sample soils. It is suggested that organic carbon could be important for the emission of $N_2$O, and that the ratio of N to C needs to be identified in the process of $N_2$O soil emission.

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References

  1. 깅득수 (2001) 챔버를 이용한 농작지로부터의 기체배출량 측정과 배출특성 연구: 일산화질소 (NO)와 아질산가스 $(N_{2}O)$의 배출량 산정. 한국대기환경학회지, 17 (2), 203-212
  2. 김득수, 오진만 (2003) 밭 토양으로부터 아질산$(N_{2}O)$기체의 배출량 측정과 배출특성 한국대기환경학회지,19(5),529-540
  3. Aulakh, M.S., T.S. Khera, and J.W. Doran (2001) Mineralization and denitrification in upland, nearby saturated and flooded subtropical soil. II. Effect of organic manures varying in N content and C : N ratio. Bio Fertil Soils, 31, 168-174
  4. Cavigelli, M.A and G.P. Robertson (2001) Role of denitrifier diversity in rates of nitrous oxide consumption in a terrestrial ecosystem. Soil BioI. Biochem, 33, 297-310
  5. Cruzen, P.J. (1970) The influence of nitrogen oxides on the atmospheric ozone content. Q.J.R. Meteorol. Soc, 96, 320-325 https://doi.org/10.1002/qj.49709640815
  6. Davidson, E.A. (1991) Fl uxes of nitrous oxide and nitric oxide from terrestrial ecosystems ‘ American Society for Microbiology, Washington , D.C, 219-235
  7. Davidson, E.A., J.M. Stark, and M.K. Firestone (1990) Microbial production and consumption of nitrate in an annual grass. In: Davidson E.A. and Schimel J.P.(eds) Printed and bound in Great Britain at the University Press, Cambridge. Chapter 10, Microbial processes of production and consumption of nitric oxide, nitrous oxide and methane
  8. Duxbury, J.M., L.A. Harper, and A.R. Mosier (1993) Contributions of agroecosystems to global climate change In Agroecosystem Effects on Radatively Importnat Trace Gases and Global Climate Change. L.A Harper, A.R. Mosier, J.M. Duxbury, and D.E. Rolston. 1-18. ASA Special Publication No. 55. Amer Soc. Agro., Madison WI
  9. Godde, M, and R. Conard (1999) Immediate and adaptation temperature effects on nitric oxide production and nitrous oxide release from nitrification and denitrification in two soils. Bioi Fertil Soils, 30, 33-40
  10. Holtan-Hartwig, L., P. Dorsch, and L.R. Bakken(2002) Low temperature control of soil denitrifying communities: kinetics of $N_{2}O$ production and reduction. Soil. BioI. Biochem, (in press)
  11. IPCC (1994) Radiative Forcing of Climate Change-Intergovernmental Panel on Climate Change, WMO-UNEP
  12. Jorgensen, B.J. and R.N. lorgensen (1996) Filed scale laboratory study of factors affection NO emission from a rye stubble filed on sandy loam soil. Boil Fertil Soils, 25, 366-371
  13. Khalil, M.A.K. and R.A. Rasmussen (1992) The global sources of nitrous oxide. J. Geophys. Res., 97, 14651-14660
  14. Kim, D-S, Y. Harazono, M.A. Baten, H. Nagai and H. Tsuruta (2002) Surface flux measurements of $CO_2$ and $N_{2}O$ from a dried rice paddy in Japan during a fal-low winter season. J. Air & Waste Manage. Assoc. 52, 416-422
  15. Kim, D.S. and J.C. Kim (2002) Soil nitric and nitrous oxide emissions from agricultural and tidal flat fields in southwestern Korea. Canadian Journal of Environ mental Engineering and Science, 1, 359-369
  16. Li, C., J. Aber, F. Stange, K.B. Bahl, and H. Papen (2000) A process-oriented model of $N_{2}O$ and NO emissions from forest soils. I. Model development. Journal of Geophysical Research, Vol 105, No, D4, 4369-4384
  17. Magg, M. and F.P. Vinther (1996) Nitrous oxide emission by nitrification and denitrification in different soil types and at different soil moisture contents and temperatures. Applied Soil Ecology, 4, 5-14
  18. Prinn, R., D. Cunnold, R. Rasmussen, P. Simmonds, F. Alyea, A. Crawford , P. Fraser, and R. Rosen (1990) Atmo spheric emissions and trends of nitrous oxide deduced from 10 years of ALE-GAGE data. J. Geophys. Res. 95, 18369-18385
  19. Stange, F., K.B. Bahl, H. Papen, S.Z. Boltenstern, C. Li, and J. Aber (2000) A process-oriented modeI of $N_{2}O$ and NO emissions from forest soils, 2. Sensitivity analysis and validation. Journal of Geophysical Research, Vol. 105, No. D4, 4385-4398.
  20. Warneck, P. (1988) Chemistry of the Natural Atmosphere Academic Press. Inc, New York. p757, 1 988
  21. Weitz, A.M., E. Linder, S. Frolking, P.M. Crill, and M. Keller (2001) $N_{2}O$ emissions from humid tropical agriculture soils: Effects of soil moisture and nitrogen availability. Soil BioI. Biochem , 33, 1077-1093.