In contrast, NO3− N was mobile and

In contrast, NO3− N was mobile and descended through the profile (Liao et al., 2006), it was greatly changed by the N application rates and basal–top-dressing ratios.
Soil NO3− N content in the 0–60 cm soil layer before jointing increased with increasing basal N rate, and there was an accumulation peak in 40–60 cm soil layer at jointing (133 DAS), indicating that NO3− N leached significantly to deep layer soil before jointing, and might leach into groundwater since the ground water level in the this region is usually less than 1 m (Liang et al., 2011).
After topdressing, the NO3− N content in the 40–60 cm soil layer increased at booting stage only in treatment N300, suggesting that only a topdressing N rate exceeding the fixed absorption capacity of the soil and plants would result in NO3− N leaching (Liu et al., 2003; Gheysari et al.,
2009),
but the leaching amount was lower than that in the period before jointing, which is consistent with the result of Sieling and
Kage (2006),
who found most of the N leached from arable soils was in earlier growth stage when the plant demand was low.
However,some studies have reported that nitrogen rates and timing of applications did not influence N fertilizer or nitrate movement in the soil profile (Ottman and Pope, 2000; Zhang et al., 2004).
The different results are possibly due to the different N supply (Sielingand Kage, 2006; Liang et al., 2011), rainfall and water supply (Asadiet al., 2002; Jalali, 2005), temperature (Liang et al., 2011), previous cropping, etc. (Goulding et al., 2000),
which affect NO3− N leaching significantly.
In the middle and lower Yangtze River Basin in China,rice and wheat are rotated intensively, and the climate is warm
wet and much rainy, generally resulted in the high soil moisture in wheat growth season.
Thus, excessive N fertilizer applications lead to NO3− N leaching easily