Abstract
Abstract. Inaccurate estimate of the largest terrestrial carbon pool, soil organic carbon (SOC) stock, is the major source of uncertainty in simulating feedback of climate warming on ecosystem–atmosphere carbon dioxide exchange by process-based ecosystem and soil carbon models. Although the models need to simplify complex environmental processes of soil carbon sequestration, in a large mosaic of environments a missing key driver could lead to a modeling bias in predictions of SOC stock change.We aimed to evaluate SOC stock estimates of process-based models (Yasso07, Q, and CENTURY soil sub-model v4) against a massive Swedish forest soil inventory data set (3230 samples) organized by a recursive partitioning method into distinct soil groups with underlying SOC stock development linked to physicochemical conditions.For two-thirds of measurements all models predicted accurate SOC stock levels regardless of the detail of input data, e.g., whether they ignored or included soil properties. However, in fertile sites with high N deposition, high cation exchange capacity, or moderately increased soil water content, Yasso07 and Q models underestimated SOC stocks. In comparison to Yasso07 and Q, accounting for the site-specific soil characteristics (e. g. clay content and topsoil mineral N) by CENTURY improved SOC stock estimates for sites with high clay content, but not for sites with high N deposition.Our analysis suggested that the soils with poorly predicted SOC stocks, as characterized by the high nutrient status and well-sorted parent material, indeed have had other predominant drivers of SOC stabilization lacking in the models, presumably the mycorrhizal organic uptake and organo-mineral stabilization processes. Our results imply that the role of soil nutrient status as regulator of organic matter mineralization has to be re-evaluated, since correct SOC stocks are decisive for predicting future SOC change and soil CO2 efflux.
Highlights
In spite of the historical net carbon sink of boreal soils, 500 Pg of carbon since the last ice age (Rapalee et al, 1998; DeLuca and Boisvenue, 2012; Scharlemann et al, 2014), boreal soils could become a net source of carbon dioxide to the atmosphere as a result of long-term climate warming (Kirschbaum, 2000; Amundson, 2001)
The linear regression of mean levels of all 10 physicochemical soil groups between the modeled and measured soil organic carbon (SOC) stocks showed smaller underestimation of CENTURY compared to Yasso07 and Q models (Fig. 4)
Varying CENTURY parameters of site-specific topsoil mineral nitrogen and C / N ratio of the litterfall showed that this impact on SOC stocks estimates was small in comparison to sensitivity of SOC stock estimates to litterfall (Fig. S12)
Summary
In spite of the historical net carbon sink of boreal soils, 500 Pg of carbon since the last ice age (Rapalee et al, 1998; DeLuca and Boisvenue, 2012; Scharlemann et al, 2014), boreal soils could become a net source of carbon dioxide to the atmosphere as a result of long-term climate warming (Kirschbaum, 2000; Amundson, 2001) They have the potential to release larger quantities of carbon than all anthropogenic carbon emissions combined (337 Pg; Boden et al, 2010). The poor agreement between the modeled and measured SOC stocks (Todd-Brown et al, 2013) could indicate missing biotic or abiotic drivers of long-term carbon storage (Schmidt et al, 2011; Averill et al, 2014)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
