Research
Extension
Courses
Consumers
--------------------------
Virtual
Tours Student
& Job Opportunities News
Articles Standards
--------------------------
Market
Information Events
Issues
Animal Welfare Strategic
Plans --------------------------
Site Map
Links
Award-winners
Organic Eprints
Effects of input level and crop diversity on soil nitrate-N, extractable
P, aggregation, organic C and N, and nutrient balance in the Canadian
Prairie
S. S. Malhi1 , S. A. Brandt2, R. Lemke3, A. P. Moulin4 and R. P. Zentner5
Abstract
A field experiment was conducted from 1995 to 2006 on a Dark Brown Chernozem
(Typic Boroll) loam soil at Scott, Saskatchewan, Canada to
determine the influence of input level and crop diversity on accumulation
and distribution of nitrate-N and extractable P in the soil profile,
and soil pH, dry aggregation, organic C and N, and nutrient balance
sheets in the second 6-year rotation cycle (2001–2006).
Treatments were combinations of three input levels (organic input under conventional tillage—ORG; reduced input under no-till—RED; and high input under conventional tillage—HIGH), three crop diversities (fallow-based rotations with low crop diversity—LOW; diversified rotations using annual cereal, oilseed and pulse grain crops—DAG; and diversified rotations using annual grain and perennial forage crops—DAP), and six crop phases including green manure (GM), chem-fallow or tilled-fallow (F).
Amount of nitrate-N in 0-240 cm soil was usually highest under the HIGH input-LOW crop diversity treatment and lowest under the ORG input-DAP crop diversity treatment. The distribution of nitrate-N in various soil depths suggested downward movement of nitrate-N up to 240 cm depth, especially with LOW crop diversity compared to DAP crop diversity, and with HIGH input. In some years, the ORG input systems had higher nitrate-N than the RED or HIGH input systems, which was attributed to low extractable P in soil for optimum crop growth and reduced nutrient uptake with ORG input management.
Extractable P in soil was higher by a small margin for HIGH or RED input relative to ORG input in the 0–15 cm layer, suggesting little downward movement of P. Crop diversity did not affect extractable soil P due to the low baseline levels of P in this soil.
The proportion of fine dry aggregates (<1.3 mm, erodible fraction) in 0–5 cm soil was highest with LOW crop diversity-HIGH input system, and lowest with DAG diversity-RED input system. The opposite was true for large aggregates (>12.7 mm). Wet aggregate stability was higher for RED input compared to ORG and HIGH input, which was attributed to the increase in the concentration of organic C in aggregates in the RED input system.
Amount of light fraction organic matter (LFOM), light fraction organic C (LFOC) and light fraction organic N (LFON) in 0–15 cm soil was higher for RED input compared to ORG and HIGH inputs, and higher for DAG and DAP crop diversities than for LOW crop diversity.
Soil N and P were usually deficient under ORG input management, but large amounts of N and P were unaccounted for, or in surplus, under RED and HIGH inputs, despite a marked increase in plant N and P uptake and crop yield compared to ORG input.
Overall, our findings suggest that soil quality can be improved and
nutrient accumulation in the soil profile can be minimized by increasing
cropping frequency, reducing/eliminating tillage, and using appropriate
combinations of fertilizer input and diversified cropping.
Source
Nutrient Cycling in Agroecosystems (2009) 84: 1-22
Author Locations and Affiliations
(1) Agriculture and Agri-Food Canada, P.O. Box 1240, Melfort, SK, Canada,
S0E 1A0
(2) Agriculture and Agri-Food Canada, P.O. Box 10, Scott, SK, Canada,
S0K 4A0
(3) Agriculture and Agri-Food Canada, Saskatoon, SK, Canada, S7N 0X2
(4) Agriculture and Agri-Food Canada, Brandon, MB, Canada, R7A 5Y3
(5) Agriculture and Agri-Food Canada, Swift Current, SK, Canada, S9H
3X2
en français
Posted November 2008