Abstract
PurposeAn 8-week incubation study was conducted to monitor soil inorganic nitrogen (N), dissolved organic carbon (DOC), greenhouse gases (GHG) [CO2, N2O and CH4] and cumulative global warming potential (GWP) in dryland soil.MethodsSoil was amended with variable rates of compost (zero, 15, 30 and 45 dry Mg ha−1) and soil moistures [5% (dry), 7% (normal) and 14% (wet) water filled pore space (WFPS)] and experienced biweekly temperature transitions from 5 °C (late winter) to 10 °C (early spring) to 15 °C (late spring) to 25 °C (early summer).ResultsThe addition of 30 and 45 Mg ha−1 compost enhanced N mineralization with 13% more soil inorganic N (7.49 and 7.72 µg Ng−1 day−1, respectively) during early summer compared with lower compost rates. Normal and wet soils had 35% more DOC in the late spring (an average of 34 µg g−1 day−1) compared to the dry WFPS, but transitioning from late spring to early summer, DOC at all soil WFPS levels increased. Highest rates of compost were not significant sources of GHG with normal soil WFPS, compared with lower compost rates. Carbon dioxide emissions increased by 59 and 15%, respectively, as soil WFPS increased from dry to normal and normal to wet. Soils with normal WFPS were the most effective CH4 sink.ConclusionOne-time application of high compost rates to dryland soils leads to enhanced N and C mineralization under normal soil moisture and warmer temperature of the summer but will not pose significant global warming dangers to the environment through GHG emissions since soils are rarely wet.
Highlights
Soil organic amendments such as composted feedlot manure, are important and sometimes, the only sources of nutrients available to dryland organic winter wheat (Avena sativa L.) farmers in the Northern High Plains (NHP) ecoregion of the United States (Larney and Angers 2012)
The objective of this study was to monitor the soil C and N dynamics, greenhouse gas (GHG) emissions, and cumulative global warming potential (GWP) of dryland soil amended with different rates of compost (0, 15, 30 and 45 dry Mg ha−1) and soil moisture contents [5% water filled pore space (WFPS), 7% and 14%] and transitioning through the various seasons of the year
Even at the lowest temperature (5 °C, late winter) (Table 2), increasing the soil % WFPS by 2, appeared to have the greatest impact on C O2 emissions; either due to the liberation of CO2 trapped in soil macropores (Bista et al 2017) or chemical transformations of inorganic carbonates (Smart and Penuelas 2005)
Summary
Soil organic amendments such as composted feedlot manure ( referred to as “compost”), are important and sometimes, the only sources of nutrients available to dryland organic winter wheat (Avena sativa L.) farmers in the Northern High Plains (NHP) ecoregion of the United States (Larney and Angers 2012). This ecoregion experiences very high variability in precipitation and temperatures during distinct annual seasons (winter, spring, summer and fall). Especially by summer rains, has triggered immediate soil microbial activity (Austin et al 2004) and caused temporary increases in mineral and labile organic N and C and GHG pulses (Norton et al 2008)
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