Soil surface CO2 flux increases with successional time in a fire scar chronosequence of Canadian boreal jack pine forest

Abstract. To fully understand the carbon (C) cycle impacts of forest fires, both C emissions during the fire and post-disturbance fluxes need to be considered. The latter are dominated by soil surface CO 2 flux ( F s ), which is still subject to large uncertainties. Fire is generally regarded as the most important factor influencing succession in the boreal forest biome and fire dependant species such as jack pine are widespread. In May 2007, we took concurrent F s and soil temperature ( T s ) measurements in boreal jack pine fire scars aged between 0 and 59 years since fire. To allow comparisons between scars, we adjusted F s for T s ( F s T ) using a Q 10 of 2. Mean F s T ranged from 0.56 (± 0.30 sd) to 1.94 (± 0.74 sd) μmol CO 2 m −2 s −1 . Our results indicate a difference in mean F s T between recently burned (4 to 8 days post fire) and non-burned mature (59 years since fire) forest ( P P = 0.785). There was a difference in mean F s T between previously young (16 years since fire) and intermediate aged (32 years since fire) scars that were both subject to fire in 2007 ( P F s T between mature (59 years since fire) and intermediate aged (32 years since fire) scars that were both subjected to fire in 2007 ( P = 0.226). Furthermore, there was no difference in mean F s T between mature (59 years since fire) and young scars (16 years since fire) that were both subjected to fire in 2007 ( P = 0.186). There was an increase in F s T with time since fire for the chronosequence 0, 16 and 59 years post fire ( P F s in boreal jack pine fire scars and will facilitate meta-analyses of F s in fire scar chronosequences.