Ca. Campbell et al., Seasonal trends in soil biochemical attributes: Effects of crop managementon a Black Chernozem, CAN J SOIL, 79(1), 1999, pp. 85-97
Knowledge of the response of soil biochemical attributes to crop management
and growing season weather is important for assessing soil quality and fer
tility. Long-term (38-39 yr) crop rotations on a Black Chernozem at Indian
Head, Saskatchewan, were sampled (0- to 7.5-cm depth) between early May and
mid-October, 11 times in 1995 and 9 times in 1996. We assessed the effect
of cropping frequency [fallow-wheat (Triticum aestivum L.) (F-W) vs. F-W-W,
vs. Continuous (Cont) W], fertilizers (unfertilized vs. N + P applied), st
raw harvesting, legume green-manure (GM) in GM-W-W (unfertilized), and legu
me-grass hay (H) in F-W-W-H-H-H (unfertilized) systems. Changes in organic
C and total N (OC, TN), microbial biomass C (MBC), light fraction C and N (
LFC and LFN), mineralizable C and N (C-min and N-min), and water-soluble or
ganic C (WSOC) were monitored. Organic C and TN were constant and unaffecte
d by rotation phase during the season, but most of the other more labile so
il biochemical attributes varied during the season. Much of this temporal v
ariability was associated with changes in soil moisture, temperature and pr
ecipitation, and with rhizodeposition in some cases. Whenever conditions fa
voured rapid decomposition in situ (e.g., high moisture, temperature and/or
precipitation) we obtained lower values for the more labile attributes in
subsequent laboratory measurements. Seasonal trends in the more labile attr
iutes were more pronounced in 1995 (a much wetter year) than in 1996, and t
he proportion of the variability attributable to weather conditions was gre
ater in 1995 than in 1996 (viz., R-2 ranged from 20 to 44% in 1996 and from
37 to 60% in 1995). Seasonal variability was greater in the more fertile t
reatments [e.g., Cent W (Fert) and F-W-W-H-H-H) than in F-W or Cent W (Unfe
rt). Seasonal variability in LF was unaffected by cropping. Light fraction
was lower in 1995 than 1996 because of faster decomposition in 1995 (335 mm
of growing season precipitation compared to 157 mm in 1996). Microbial bio
mass was not influenced by cropping in 1996, but in 1995 it was higher in c
ropped than in fallow phases of the rotations, suggesting a positive effect
of rhizodeposition. Water-soluble organic C was greatest in the more ferti
le treatments and in cropped than in fallow phases. Mineralizable C and N w
ere greater in cropped than in fallow rotation phases in 1995, but unaffect
ed by cropping in 1996. Further, C-min and N-min were higher in 1996 than i
n 1995, likely due to more rapid decomposition in the wetter 1995. Over the
last 10 yr of this experiment LFC and C-min have increased markedly in the
more fertile treatments [e.g., Cent W (Fert), F-W-W-H-H-H], but have hardl
y changed in the less fertile treatments such as F-W or Cent W (Unfert). In
this period the less labile attributes (e.g., OC) have hardly changed in a
ny treatment.