Effects of broad-leaf crop frequency in various rotations on soil organic C and N, and inorganic N in a Dark Brown soil

Abstract

The objective of this study was to determine the impact of frequency of broad-leaf crops canola and pea in various crop rotations on pH, total organic C (TOC), total organic N (TON), light fraction organic C (LFOC) and light fraction organic N (LFON) in the 0 - 7.5 and 7.5 - 15 cm soil depths in autumn 2009 after 12 years (1998-2009) on a Dark Brown Chernozem (Typic Boroll) loam at Scott, Saskatchewan, Canada. The field ex-periment contained monoculture canola (herbicide tolerant and blackleg resistant hybrid) and monoculture pea compared with rotations that contained these crops every 2-, 3-, and 4-yr with wheat. There was no effect of crop rotation duration and crop phase on soil pH. Mass of TOC and TON in the 0 - 15 cm soil was greater in canola phase than pea phase in the 1-yr (monoculture) and 2-yr crop rotations, while the opposite was true in the 3-yr and 4-yr crop rotations. Mass of TOC and TON (averaged across crop phases,) in soil generally increased with increasing crop rotation duration, with the maximum in the 4-yr rotation while no difference in the 1-yr and 2-yr rotations. Mass of LFOC and LFON in soil was greater in canola phase than pea phase in the 1-yr, 2-yr and 3-yr rotations, but the opposite was true in the 4-yr rotation. There was no consistent effect of crop rotation duration on mass of LFOC and LFON. The N balance sheet over the 1998 to 2009 period indicated large amounts of unaccounted N for monoculture pea, suggesting a great potential for N loss from the soil-plant system in this treatment through nitrate leaching and/or denitrification. In conclusion, the findings suggest that the quantity of organic C and N can be maximized by increasing duration of crop rotation and by including hybrid canola in the rotation.

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Malhi, S. , Lemke, R. and Brandt, S. (2012) Effects of broad-leaf crop frequency in various rotations on soil organic C and N, and inorganic N in a Dark Brown soil. Agricultural Sciences, 3, 854-864. doi: 10.4236/as.2012.36104.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1] Christen, O. and Sieling, K. (1995) Effect of different preceding crops and crop rotations on yield of winter oil-seed rape (Brassica napus L.) J. Agronomy and Crop Science, 174, 265-271.
[2] Pearse, P.R., Morrall, A.A., Kutcher, H.R., Keri, M., Kaminski, D., Gugel, R., Anderson, K., Trail, C. and Greuel, W. (2001) Survey of canola diseases in Saskatchewan, 2000. Canadian Plant Distribution Survey, 81, 105-107.
[3] Johnston, A.M., Kutcher, H.R. and Bailey, K.L. (2005) Impact of crop sequence decisions in the Saskatchewan Parkland. Canadian Journal of Plant Science, 85, 95-102.
[4] Dalal, R.C. (1989) Long-term effects of notillage, crop residue, and nitrogen application on properties of a Vertsol. Soil Science Society of America Journal, 53, 1511-1515.
[5] Havlin, J.L., Kissel, D.E., Maddux, L.D. and Long, J.H. (1990) Crop rotation and tillage effects on soil organic carbon and nitrogen. Soil Science Society of America Journal, 54, 448-452.
[6] Janzen, H.H., Campbell, C.A., Brandt, S.A., Lafond, G.P. and Townley-Smith, L. (1992) Light-fraction organic matter in soil from long term rotations. Soil Science Society of America Journal, 56, 1799-1806.
[7] Halvorson, A.D., Wienhold, B.J. and Black, A.L. (2002) Tillage, nitrogen and cropping system effects on soil carbon sequestration. Soil Science Society of America Journal, 66, 906-912.
[8] Liang, B.C., McConkey, B.G., Schoenau, J.J., Curtin, D., Campbell, C.A., Moulin, A., Lafond, G.P., Brandt, S.A. and Wang, H. (2003) Effect of tillage and crop rotations on the light fraction organic carbon and carbon mineralization in Chernozemic soils of Saskatchewan. Canadian Journal of Soil Science, 83, 65-72.
[9] McConkey, B.G., Liang, B.C., Campbell, C.A., Curtin, D., Moulin, A., Brandt, S.A. and Lafond, G.P. (2003) Crop rotation and tillage impact on carbon sequestration in canadian prairie soils. Soil and Tillage Research, 74, 81-90.
[10] Malhi, S.S., Moulin, A.P., Johnston, A.M. and Kutcher, R.H. (2008) Short-term and long-term effects of tillage and crop rotation on some soil physical and biological properties in a Black Chernozem soil in northeastern Saskatchewan. Canadian Journal of Soil Science, 88, 273-282.
[11] Malhi, S.S., Brandt, S.A. and Kutcher, H.R. (2011a) Effects of broad-leaf crops frequency and fungicide application in various crop rotations on seed yield, and accumulation of nitrate-N and extractable P in soil after eight years in a Dark Brown Chernozem in Saskatchewan. Communications in Soil Science and Plant Analysis, 42, 2795-2812.
[12] Culley, J.L.B. (1993) Density and compressibility. In: M.R. Carter (ed), Soil Sampling and Methods of Analysis. Lewis Publishers, Boca Raton, FL, U.S.A., 529-549.
[13] Technicon Industrial Systems. (1977) Industrial/simultaneous determination of nitrogen and/or phosphorus in BD acid digests. Industrial Method 334-74W/Bt. Technicon Industrial Systems, Tarrytown, NY, U.S.A.
[14] Izaurralde, R.C., Nyborg, M., Solberg, E.D., Janzen, H.H., Arshad, M.A., Malhi, S.S. and Molina-Ayala, M. (1997) Carbon storage in eroded soils after five years of reclamation techniques. In: Lal, R., Kimble, J.M., Follett, R.F. and Stewart, B.A., Eds., Management of carbon sequestration in soil. Adv Soil Sci, CRC Press, Boca Raton, FL, U.S.A., 369-385.
[15] Technicon Industrial Systems. (1973a) Ammonium in water and waste water. Industrial Method No. 90-70W-B. Revised January 1978. Technicon Industrial Systems, Tarrytown, NY U.S.A.
[16] Technicon Industrial Systems. (1973b) Nitrate in water and waste water. Industrial Method No. 100-70W-B. Revised January 1978. Technicon Industrial Systems, Tarrytown, NY, U.S.A.
[17] IPCC (Integovernmental Panel on Climate Change). (2006) N2O emissions from managed soils, and CO2 emissions from lime and urea application. Chapter 11. In: IPCC guidelines for national greenhouse gas inventories. Vol. 4: Agriculture, forestry and other land use. Institute for Global Environment Strategies, Hayama, Japan.
[18] Lupwayi, N.Z., Clayton, G.W., O’Donovan, J.T., Harker, K.N., Turkington, T.K. and Soon, Y.K. (2007) Phosphorus release during decomposition of crop residues under conventional and zero tillage. Soil and Tillage Research, 95, 231-239.
[19] Malhi, S.S. and Lemke, R. (2007) Tillage, crop residue and N fertilizer effects on crop yield, nutrient uptake, soil quality and greenhouse gas emissions in the second 4-yr rotation cycle. Soil and Tillage Research, 96, 269-283.
[20] SAS Institute, Inc. (2004) SAS product documentation. Version 8. Available at http://support.sas.com/documentation/onlinedoc/index.html (verified 17 July 2009). SAS Institute, Cary, NC, U.S.A.
[21] Malhi, S.S., Brandt, S.A., Lemke, R., Moulin, A.P. and Zentner, R.P. (2009) Effects of input level and crop diversity on soil nitrate-N, extractable P, aggregation, organic C and N, and N and P balance in the Canadian Prairie. Nutrient Cycling in Agroecosystems Online. DOI 10.1007/s10705-008-9220-0.
[22] Campbell, C.A., Vanden-Bygaart, A.J., Grant, B., Zentner, R.P., McConkey, B.G., Lemke, R., Gregorich, E.G. and Fernandez,M. R. (2007) Quantifying carbon sequestration in a conventionally tilled crop rotation study in southwestern Saskatchewan. Canadian Journal of Soil Science, 87, 23–38.
[23] Comeau, L. (2012) The influence of lentil, canola, pea and wheat on carbon and nitrogen dynamics in two Chernozemic soils. M.Sc. thesis. University of Saskatchewan, Saskatoon Saskatchewan, Canada.
[24] Gregorich, E.G. and Janzen, H.H. (1995) Storage of soil carbon in the light fraction and macroorganic. In: Carter, M.R. and Stewart, B.A., Eds., Structure and organic matter storage in agricultural soils. Advances in Soil Science, Lewis Publishers, CRC Press, Boca Raton, FL, U.S.A., 167-190
[25] Malhi, S.S., Nyborg, M., Goddard, T. and Puurveen, D. (2010) Long-term tillage, straw and N rate effects on quantity and quality of organic C and N in a Gray Luvisol soil. Nutrient Cycling in Agroecosystems, Online. 16 September 2010. DOI 10.1007/s10705-010-9399-8.
[26] Malhi, S.S., Nyborg, M., Goddard, T. and Puurveen, D. (2011b). Long-term tillage, straw management and N fertilization effects on quantity and quality of organic C and N in a Black Chernozem soil. Nutrient Cycling in Agroecosystems, Online. 16 February 2011. DOI 10.1007/s10705-011-9424-6.
[27] Malhi, S.S., Nyborg, M., Solberg, E.D., McConkey, B., Dyck, M. and Puurveen, D. (2011c) Long-term straw management and N fertilizer rate effects on quantity and quality of organic C and N, and some chemical properties in two contrasting soils in western Canada. Biology and Fertility of Soils, 47, 785-800. DOI 10.1007/s00374-011-0587-8.
[28] Malhi, S.S., Harapiak, J.T., Nyborg, M. and Flore, N.A. (1991) Soil chemical properties after long-term N fertilization of bromegrass: Nitrogen rate. Communications in Soil Science and Plant Analysis, 22, 1447-1458.
[29] Malhi, S.S., Harapiak, J.T., Gill, K.S. and Flore, N. (2002) Long-term N rates and subsequent lime application effects on macroelements concentration in soil and in bromegrass hay. Journal of Sustainable Agriculture, 21, 79-97.
[30] Guillard, K., Griffin, G.F., Allinson, D.W., Yamartino, W.R., Rafey, M.M. and Pietryzk, S.W. 1995. Nitrogen utilization of selected cropping systems in the U.S. northeast. II. Soil profile nitrate distribution and accumulation. Agronomy Journal, 87, 199-207.
[31] Zhang, W.L., Tian, Z.X., Zhang, N. and Li, X.O. (1996) Nitrate pollution of groundwater in northern China. Agriculture, Ecosystem and Environment, 59, 223–231.
[32] Yuan, X., Tong, Y., Yang, X., Li, X. and Zhang, F. (2000) Effect of organic manure on soil nitrate accumulation. Soil Environmental Science, 9, 197–200.
[33] [33] Heaney, D.J., Nyborg, M., Solberg, E.D., Malhi, S.S. and Ashworth, J. (1992) Overwinter nitrate loss and denitrification potential of cultivated soils in Alberta. Soil Biology and Biochemistry, 24, 877-884.
[34] Nyborg, M., Laidlaw, J.W., Solberg, E.D. and Malhi, S.S. (1997) Denitrification and nitrous oxide emissions from soil during spring thaw in a Malmo loam, Alberta. Canadian Journal of Soil Science, 77, 53-160.

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