THE EFFECT OF INCREASING APPLICATION RATE OF GRANULAR CALCIUM AMMONIUM-NITRATE ON NET NITRIFICATION IN A LABORATORY STUDY OF GRASSLAND SOILS

Soil incubation studies were undertaken in controlled environment cabi nets at 15 degrees C to investigate the effect of increasing applicati on rates of calcium ammonium nitrate (CAN) on net nitrification in two grassland soils. Granular CAN was applied to the surface of freshly c ollected, moist soil, at a rate equivalent to 0, 100, 200, 400, 800 an d 1600 mu g NH4+-N and NO3--N per gram of oven dry soil. In half the t reatments finely ground CaCO3 was incorporated into the moist soil to raise the starting pH. Changes in soil mineral N and pH were measured at weekly intervals up to six-weeks. The most probable number (MPN) te chnique was used to enumerate the NH4+-N and NO2--N oxidizers at the b eginning and end of the incubation. At low rates of CAN application th ere was considerable NH4+-N oxidation to NO3--N during the incubation of both soils. Lime stimulated this N transformation. At high applicat ion rates (i.e. 800 and 1600 ppm) there was little change in NH4+-N or NO3--N on either soil during the 6 week incubation, in the presence o r absence of lime. The rate of NO3--N produced peaked at 5.6 and 3.8 m g NO3--N kg(-1) d(-1) on soil 1 and 2 respectively, in the presence of lime. Above a level of 400 ppm CAN (equivalent to 38 kg N ha(-1)) the rate of NO3--N produced decreased. The higher rate of net nitrificati on in soil 1 compared with soil 2 was probably due to a higher number of nitrifying bacteria. Although high rates of CAN decreased the nitri fying activity of both soils there was little difference between treat ments in the actual numbers of NH4+-N and NO2--N oxidizers determined by the MPN technique. The results showed that the rate of granular CAN applied to the soil surface can influence the local activity of nitri fying bacteria and subsequent N transformations. At application rates of CAN generally used agriculturally for grass production, it is likel y that net nitrification of the NH4+-N in the fertilizer granule will be inhibited.