August 1998 were 4128 and 273 kg/hm

August 1998 were 4128 and 273 kg/hm2, respectively, and more runoff occurrence was
observed in this year than several previous years (Shi et al., 1999). In addition, according
to the results using Participatory Rural Appraisals (PRA) method in the Erochina project
(Erochina project report), crop residues like millet and soybean stalks were fed to animals,
while maize and sunflower stalks were used as fuel for cooking. So only low amount of
residues return to the cropland resulted in low C inputs.
Table 1 showed that TN displayed similar pattern to SOM. This similarity may be
related to SOM influencing N retention and supply (Brubaker et al., 1993). Total N content
with low variability (S.D. = 0.011 for all data) also showed significant differences among
the seven land uses (Table 1). Measurements of TN indicated that the highest content
corresponded to soils from noncultivated lands such as the woodland (0.058%) and
grassland (0.05%), followed by soils under the orchard (0.046%), intercropping land
(0.037%), shrub land (0.035%), cropland (0.032%) and fallow land (0.031%).
Unlike SOM and TN, TP did not show statistically significant differences among land
uses. Most of P is held very firmly in crystal lattices of largely insoluble forms, such as
various Ca, Fe and AlPO4

s, and also is chemically bonded to the surface of clay minerals
(Chen and Zhang, 1991). These may result in relatively small differences in the average
values of TP ranging from 0.056% (grassland) to 0.060% (woodland, orchard and
intercropping land). Moreover, the variability of TP is very low (S.D. varying between
0.002 and 0.006) in the seven land uses.
Significant differences in AN were detected among the seven land use types at the
confidence level of 99% (Table 1). The highest value of AN content (4.540 mg/100 g) was
measured in soils under the woodland. This may be due to more litters, porosity and high
soil moisture to improve microbial activity. Although additional N fertilizer amount of
about 50 kg/ha as anhydrous NH3 was applied to the cropland, its AN content had a low
level. Poorer macroaggregates due to periodical tillage (Islam and Weil, 2000) and less
biomass return on harvested land probably account for the lower AN level in the cropland.
The differences in AP content were statistically significant (at the 0.05 level) among the
seven land uses. The greatest value in AP, 3.788 mg/kg for soils from the orchard, was
almost four times than the lowest value, 0.970 mg/kg for soils of the grassland. A close
inspection of Table 1 revealed interesting characteristic of AP, which higher levels tended
to occur in the soils under the orchard and on the intercropping land with fruit trees. This
pattern of AP may be due to the fact that more mycorrhizal roots in crops especially in
leguminous crops compared to apple trees increase the efficiency of P absorption
(Pacovsky, 1986; Gnekow and Marschner, 1989).
The soil organic matter reflects the plant residues and soil organisms that have lived and
died in the soils. At the same time, its basic functions are the development and
maintenance of soil structure, water holding capacity, nutrient and organic carbon storage,
and the maintenance of biological activity. Thus, SOM is the best surrogate for soil quality
(Dumanski and Pieri, 2000; Murage et al., 2000). As the soil organic matter is consumed
and even depleted, it could not sustain economic yields of crops and the cropland was
usually abandoned for fallow in order to recover soil fertility. Therefore, SOM on the
fallow land may provide critical value, which is considered as having high risk for soil
degradation under present climate and management. The critical value is very important
for maintaining soil nutrients below which the yields of crops remain very low andunstable and where the erosional processes may become active, resulting in further soil
nutrient depletion and land degradation. In this study, the measured minimum value of
SOM for soils from the fallow land was 0.44%, which just had 43.7% and 51.9% SOM of
those from the woodland and grassland. Therefore, the SOM value of 0.44% must be
considered a key indicator for the abandonment of hilly cultivated land under present
management practices and existing climate conditions of the study area. Our results
demonstrated that nearly half of the cropland in the catchment had SOM with lower values
than this key value. Moreover, these cultivated lands produced poorer yields noted by
PRA investigation in our project.