Nitrous oxide emissions from soils with different vertical soil moisture distribution patterns

• Autorzy: Wei Q. , Xu J. , Yang S. , Dalson T.
• Języki publikacji: EN

Abstrakty

EN

To reveal the impact of vertical non-uniform distribution of soil moisture on nitrous oxide (N2O) emissions, incubated experiments were conducted from April to August 2013 on silty clay and sandy loam with four watering regimes [surface watering (SW) and subsurface watering application to levels 12, 15, and 18 cm below soil surface (SUW12, SUW15, SUW18)]. Short-term pulse emissions of N2O from both soils during the drying process were observed. The soil water-filled pore space (WFPS) at 0-12 cm depths for peak N2O fluxes in SW and SUW soils fell within 34-66%, 22-72%, 25-35%, and 19-39% for silty clay and sandy loam, respectively. Our results also suggest that the N2O fluxes from soil of sily clay with higher N content are much higher than that from sandy loam, and N2O were more easily influenced by soil moisture in SW soils than in SUW soils. However, more research is needed to identify an ideal soil-wetting pattern and the way to realize the ideal soil-wetting pattern, especially on soil with plant growth and fertilization.

• Wydawca: -
• Czasopismo: Polish Journal of Environmental Studies
• Rocznik: 2016
• Tom: 25
• Numer: 6
• Opis fizyczny: p.2623-2631,fig.,ref.

Twórcy

autor

Wei Q.

• State Key Laboratory of Hydrology–Water Resources and Hydraulic Engineering, Hohai University, Nanjing 210098, China
• College of Water Conservancy and Hydropower Engineering, Hohai University, Nanjing 210098, China

autor

Xu J.

• State Key Laboratory of Hydrology–Water Resources and Hydraulic Engineering, Hohai University, Nanjing 210098, China
• College of Water Conservancy and Hydropower Engineering, Hohai University, Nanjing 210098, China

autor

Yang S.

• State Key Laboratory of Hydrology–Water Resources and Hydraulic Engineering, Hohai University, Nanjing 210098, Chin
• College of Water Conservancy and Hydropower Engineering, Hohai University, Nanjing 210098, China

autor

Dalson T.

• College of Water Conservancy and Hydropower Engineering, Hohai University, Nanjing 210098, China

Bibliografia

• 1. IPCC. In: Metz B., Davidson OR8, Bosch PR(eds) Climate change 2007: mitigation, constribution of Working Group III to the fourth assessment report of the intergovern-mental panel on climate change. Cambridge University Press, Cambridge. 2007.
• 2. BESSOU C., MARY B., LEONARD J., ROUSSEL M., GREHAN E., GABRIELLE B. Modelling soil compaction impacts on nitrous oxide emissions in arable fields. Eur. J. Soil. Sci 61, 348, 2010.
• 3. XIA Y., LI Y, LI X., GUO M., SHE D., YAN X. Diurnal pattern in nitrous oxide emissions from a sewage-enriched river. Chemosphere 92, 421, 2013.
• 4. SYP A., FABER A., BORZECKA-WALKER M., OSUCH D. Assessment of Greenhouse Gas Emissions Winter Wheat Farms Using Data Envelopment Analysis Approach. Pol. J. Environ. Stud 24, 2197, 2015.
• 5. FAO. World Agricultural Towards 2015/2030: an FAO Perspetive. FAO, Rome. 2003.
• 6. HADI A., INUBUSHI K., YAGI K. Effect of water management on greenhouse gas emissions and microbial properties of paddy soils in Japan and Indonesia. Paddy Water Environ 8, 319, 2010.
• 7. JIAO Z.H., HOU A.X., SHI Y., HUANG G.H., WANG Y.H., CHEN X. Water management influencing methane and nitrous oxide emissions from rice field in relation to soil redox and microbial community. Commun. Soil. Sci. Plant. Anal 37, 1889, 2003.
• 8. DING L. Preliminary Study of Processes of Nitrous Oxide Emission from Soil and Plant in the Northest Farmland [dissertation]. Jilin Agricultural University. 2008.
• 9. YAO Z.S., ZHOU Z.X., ZHENG X.H., XIE B.H., MEI B.L., WANG R., BUTTERBACH-BAHL K., ZHU J.G. Effects of organic matter incorporation on nitrous oxide emissions from rice-wheat rotation ecosystems in China. Plant Soil 327, 315, 2010.
• 10. PENG S.Z., HOU H.J., XU J.Z., YANG S.H., MAO Z. Lasting effects of controlled irrigation during rice-growing season on nitrous oxide emissions from winter wheat croplands in Southeast China. Paddy. Water. Environ 11, 583, 2012.
• 11. HANSEN S., MAEHLUM J.E., BAKKEN L.R. N2O and CH4 fluxes in soil influenced by fertilization and tractor traffic. Soil. Biol. Biochem 25, 621, 1993.
• 12. KHALIL M.I., BAGGS E.M. CH4 oxidation and N2O emissions at varied soil water-filled pore spaces and headspace CH4 concentrations. Soil. Biol. Biochem 37, 1785, 2005.
• 13. SEY B.K., MANCEUR A.M., WHALEN J.K., GREORICH E.G., ROCHETTE P. Small-scale heterogeneity in carbon dioxide, nitrous oxide and methane production from aggregates of a cultivated sandy-loam soil. Soil. Biol. Biochem 40, 2468, 2008.
• 14. DING W.X., CAI Y., CAI Z.C, YAGI K., ZHENG X.H. Nitrous oxide emissions from an intensively cultivated maize–wheat rotation soil in the North China Plain. Sci. Total. Environ 373, 501, 2007.
• 15. BARTON L., SCHIPPER L.A. Nitrous oxide emissions from soils irrigated with dairy farm effluent. J. Environ. Qual 30, 1881, 2001.
• 16. HUANG J., LIU H., WANG B. CO2 and N2O Emission from Red Soil Dry-land under Long-term Fertilization. Chin. Agr. Sci. Bull 25, 428, 2009.
• 17. KALLENBACH C., ROLSTON D.E., HORWATH W.R. Cover cropping affects soil N2O and CO2 emissions differently depending on type of irrigation. Agr. Ecosyst. Environ 137, 251, 2010.
• 18. DENG J., ZHOU Z.X, ZHENG X.H, LIU C.Y., YAO Z.S., XIE B.H., CUI F., HAN S.H., ZHU J.G.. Annual emissions of nitrous oxide and nitric oxide from rice-wheat rotation and vegetable fields: a case study in the Tai-Lake region, China. Plant Soil 360, 37, 2012.
• 19. NAGATA O., YAZA T., YOSUKE Y. Nitrous oxide emissions from drained and mineral soil-dressed peatland in central Hokkaido, Japan. J. Agr. Meteorol 66, 23, 2010.
• 20. SCHEER C., WASSMANN R., KLENZLER K., LBRAGIMOV N., ESCHANOV R. Nitrous oxide emissions from fertilized, irrigated cotton (Gossypium hirsutum L.) in the Aral Sea Basin, Uzbekistan: Influence of nitrogen applications and irrigation practices. Soil. Biol. Biochem. 40, 290, 2008.
• 21. XU J.Z., WEI Q., YANG S.H, WANG Y.H, LV Y.P. Diurnal pattern of nitrous oxide emissions from soils under different vertical moisture distribution conditions. Chilean. J. Agric. Res 76, 84, 2016.
• 22. BEARE M.H., GREGORICH E.G., ST-GEORGES P. Compaction effects on CO2 and N2O production during drying and rewetting of soil. Soil. Biol. Biochem, 41, 611, 2009.
• 23. YAMAMOTO A., AKIYAMA H., NAOKAWA T., YAGI K. Effect of lime-nitrogen application on N2O emission from an Andosol vegetable field. Soil. Sci. Plant. Nutr 58, 245, 2012.
• 24. ZHONG Z.X., LI Y.E., HUA L., WAN Y.Y., JIANG N.N. Effects of different fertilizer levels on N2O flux from protected vegetable land (in Chinese with English abstract). Transactions of the CSAE 26, 269, 2010.
• 25. REPO M.E., Susiluoto S., LIND S.E., JOKINEN S., ELSAKOV V., BIAS C., VIRTANEN T., MARTIKAINEN P.J. Large N2O emissions from cryoturbated peat soil in tundra. Nature Geosci 2, 189,. 2009.
• 26. DOBBIE K.E., SMITH K.A. The effects of temperature, water-lled pore space and land use on N2O emissions from an imperfectly drained gleysol. Eur. J. Soil. Sci 52, 667, 2001.
• 27. MKHABELA M.S, GORDON R., BURTON D., MADANI A., HART W., ELMI A. Ammonia and nitrous oxide emissions from two acidic soils of Nova Scotia fertilised with liquid hog manure mixed with or without dicyandiamide. Chemosphere 65, 1381, 2006.
• 28. ZHANG H.H., HE P.J., SHAO L.M. Ammonia volatilization, N Ammonia volatilization, N2O and CO2 emissions from landfill leachate-irrigated soils. Waste. Manage 30, 119, 2010.
• 29. JIA J., SUN L., KONG X., YAN X., Xiong Z. Annual N2O and CH4 emissions from intensively managed vegetable fields in Nanjing, China. Soil. Sci. Plant. Nutr 58, 91, 2012.
• 30. TOMA Y., TAKAKAI F., DARUNG U., KURAMOCHI K., LIMIN S.H., DOHONG S., HATANO R. Nitrous oxide emission derived from soil organic matter decomposition from tropical agricultural peat soil in central Kalimantan, Indonesia. Soil. Sci. Plant. Nutr 57, 436, 2011.
• 31. HOU H.J., PENG S.Z., XU J.Z., YANG S.H., MAO Z. Seasonal variations of CH4 and N2O emissions in response to water management of paddy fields located in Southeast China. Chemosphere 89, 884, 2012.
• 32. VARGAS V.P., CANTARELLA H., MARTINS A.A., SOARES J.R., DOCARMO J.B., DEANDRADE C.A. Sugarcane Crop Residue Increases N2O and CO2 Emissions Under High Soil Moisture Conditions. Sugar. Tech 16, 174, 2014.
• 33. CONARD R., SEILER W., BUNSE G. Factors influencing the loss of fertilizer nitrogen into the atmosphere as N2O. J. Geophys. Res 88, 6709, 1983.
• 34. BOUMAN A.F. Nitrogen oxides and tropical agriculture. Nature, 392, 866, 1998.
• 35. BATEMAN E.J., BAGGS E.M. Contributions of nitrification and denitrification to N2O emissions from soils at different water-filled pore space. Biol. Fert. Soils 41, 379, 2005.
• 36. LI Y.H., WANG F., LIU R.L., ZHAO T.C., CHEN C., YANG Z.L. Study on N2O Emission in the Farmland Ecosystem of Arid Areas. J. Anhui. Agr. Sci 36, 15197, 15265, 2008.
• 37. PFAB H., PALMER I., BUEGGER F., FIEDLER S., MULLER T., RUSER R. Influence of a nitrification inhibitor and of placed N-fertilization on N2O fluxes from a vegetable cropped loamy soil. Agr. Ecosyst. Environ 150, 91, 2012.
• 38. SKIBA U., SMITH K.A., FOWLER D. Nitriftcation and denitrification as sources of nitric oxide and nitrousoxide in a sandy loam soil. Soil. Biol. Biochem 25, 1527, 1992.
• 39. PATHAK H. Emissions of nitrous oxide from soil. Curr. Sci 77, 359, 1999.
• 40. PALM C.A., ALEGRE J.C., AREVALO L., MUTUO P.K., MOSIER A.R., COE R. Nitrous oxide and methane fluxes in six different land use systems in the Peruvian Amazon. Global. Biogeochem. Cy 16, 21-1-21-13, 2002.
• 41. WLODARCZYK T., STEPNIEWSKI W., BRZEZINSKA M., ZOFIA S. Nitrate stability in loess soils under anaerobic conditions-laboratory studies. J. Plant. Nutr. Soil. Sci 167, 693, 2004.
• 42. HARRISON-KIRKA T., BEARE M.H., MEENKEN E.D., CONDRON L.M. Soil organic matter and texture affect responses to dry/wet cycles: Effects on carbon dioxide and nitrous oxide emissions. Soil. Biol. Biochem 57, 43, 2013.
• 43. DING H., CAI G.X. WANG Y.S., CHEN D. Nitrification and Denitrification Potential in Different Types of Soils in the North China Plain. Agr. Environ. Protect 20, 390, 2001.
• 44. LU F. The research of farmland N2O emission mechanism and its influence factors. J Green sci Tech, 10, 169, 2013.
• 45. ARAH J.R.M., SMITH K.A., CRICHTON I.J., LI H.S. Nitrous oxide production and denitrification in Scottish arable soils. J.Soil. Sci, 42, 351, 1991.
• 46. WANG C., LI Y.N. Experimental Research on Soil Wetting Front Infiltration of Subsurface Drip Irrigation. China. Rural. Water. Hydropower 3, 38, 2011.
• 47. WU Y.Y. Study on Greenhouse Gas Flux from Newly Created Marshes and Carbon Sink in the Three Gorges Reservoir [Master's dissertation]. Chongqing University. 2012.
• 48. MC TAGGART I.P., AKIYAMA H., TSURUTA H., BALL B.C. Influence of soil physical properties, fertiliser type and moisture tension on N2O and NO emissions from nearly saturated Japanese upland soils. Nutr. Cycl. Agroecosys, 63, 207, 2002.

Identyfikatory

DOI

10.15244/pjoes/64280