Predicting soil organic matter stability in agricultural fields through carbon and nitrogen stable isotopes
In order to evaluate the sustainability and efficiency of soil carbon sequestration measures and the
impact of different management and environmental factors, information on soil organic matter (SOM)
stability and mean residence time (MRT) is required. However, this information on SOM stability and
MRT is expensive to determine via radiocarbon dating, precluding a wide spread use of stability measurements in soil science. In this paper, we test an alternative method, first developed by Conen et al.
(2008) for undisturbed Alpine grassland systems, using C and N stable isotope ratios in more frequently
disturbed agricultural soils. Since only information on carbon and nitrogen concentrations and their
stable isotope ratios is required, it is possible to estimate the SOM stability at greatly reduced costs
compared to radiocarbon dating. Using four different experimental sites located in various climates and
soil types, this research proved the effectiveness of using the C/N ratio and d15N signature to determine
the stability of mOM (mineral associated organic matter) relative to POM (particulate organic matter) in
an intensively managed agro-ecological setting. Combining this approach with d13C measurements
allowed discriminating between different management (grassland vs cropland) and land use (till vs no
till) systems. With increasing depth the stability of mOM relative to POM increases, but less so under
tillage compared to no-till practises. Applying this approach to investigate SOM stability in different soil
aggregate fractions, it corroborates the aggregate hierarchy theory as proposed by Six et al. (2004) and
Segoli et al. (2013). The organic matter in the occluded micro-aggregate and silt & clay fractions is less
degraded than the SOM in the free micro-aggregate and silt & clay fractions. The stable isotope approach
can be particularly useful for soils with a history of burning and thus containing old charcoal particles,
preventing the use of 14C to determine the SOM stability.
Auteur(s):
De Clercq T., Heiling M., Dercon G., Resch C., Aigner M., Mayer L., Mao Y., Elsen A., Steier P., Leifeld J., Merckx R.
Nombre de pages:
Date de parution:
2015