Soil samples were air-dried and pas

Soil samples were air-dried and passed through a 2-mm pore sieve.
The following parameters were then determined from the sieved soil samples:
(a) total N by Kjeldahl (Forster, 1995),
(b) NO3-N and NH4+-N by potentiometry (Keeney and Nelson, 1982),
and (c) microbial biomass N by the fumigation method (Joergensen, 1995).
Samples of crop residues and shoots were weighed, dried at 60 8C (until constant weight) and milled.
Total N content in crop residues and grain were determined by Kjeldahl.
Yield (12% moisture) was evaluated by each farmer in the field by precision agriculture techniques using GPS.
Climate data were obtained from the records of INTA Marcos Juarez Meteorological Station.
The values of each parameter analyzed were transformed to kg ha1.
The following calculations were performed following Guarda et al. (2004):
(a) N recovery = (grain N content of non-fertilized treatment  grain N content of fertilized treatment)/fertilizer N content and
(b) agronomic efficiency = (yield of fertilized treatment  yield of non fertilized treatment)/fertilizer N content.
N balance was calculated as the difference between N fractions at harvest (soil + crop residue + grain) and N fractions at sowing (soil + crop residue + fertilizer).
We assumed that negative values mean N losses of the 0–20 cm soil surface layer where the amount and dynamics of N is more significant (Daude´n and Quı´lez, 2004).
Data were analyzed by ANOVA and LSD test for mean comparison among treatments (P < 0.05).
A t-test was performed (P < 0.05) to determine dynamics of the different N fractions between sowing and
harvest samplings in each treatment.