366-3 The Potential for Full Inversion Tillage to Increase Soil Carbon Storage during Pasture Renewal in New Zealand.

See more from this Division: ASA Section: Environmental Quality
See more from this Session: Soil-Plant-Atmosphere Interactions and Soil Carbon Dynamics in Long-Term Research Experiments

Wednesday, November 9, 2016: 8:35 AM
Phoenix Convention Center North, Room 122 A

Michael H. Beare, Soil Water and Environment Group, New Zealand Institute for Plant & Food Research, Christchurch, NEW ZEALAND, Erin Lawrence-Smith, New Zealand Institute for Plant & Food Research, Lincoln, New Zealand, Denis Curtin, New Zealand Institute for Plant & Food Research Limited, Christchurch, New Zealand and Frank Kelliher, Lincoln Research Centre, AgResearch, Lincoln, New Zealand
Abstract:
Pasture renewal (destruction and re-establishment of pasture) is promoted to livestock farmers to improve pasture performance. This typically involves shallow cultivation or direct drilling to establish new grass. Whereas shallow cultivation of soil typically results in a loss of SOC, deeper full inversion tillage (FIT) of soil would result in the burial of C-rich topsoil in closer proximity to mineral material that has a higher stabilisation capacity.  Buried SOC is expected to have a slower decomposition rate owing to less variable temperatures and more anoxic conditions. Deep FIT would also bring under-saturated mineral soil to the surface, where the deposition of SOC from high producing pastures could increase the stabilisation of SOC.  Both the slower turnover of buried SOM and greater stabilisation of new carbon on under-saturated minerals at the soil surface are expected to result in increased SOC sequestration.

There is a lack of experimental data to directly address the effect of FIT on soil C stocks in pastoral soils. We applied a simple empirical model to predicting changes in soil C stocks following a one-off application of FIT (30 cm) during pasture renewal. The model accounts for the decomposition of SOC in buried topsoil and the accumulation of C in the new topsoil (inverted subsoil). The model was used to derive national estimates of soil C sequestration under different scenarios of C accumulation efficiency, farmer adoption of FIT and pasture renewal rates.

See more from this Division: ASA Section: Environmental Quality
See more from this Session: Soil-Plant-Atmosphere Interactions and Soil Carbon Dynamics in Long-Term Research Experiments