- Institutionen för vilt, fisk och miljö, Sveriges lantbruksuniversitet
Persson, Inga-Lill; Nilsson, Mats B.; Pastor, John; Eriksson, Tobias; Bergstrom, Roger; Danell, Kjell
Large herbivores can affect the carbon cycle in boreal forests by changing productivity and plant species composition, which in turn could ultimately alter litter production, nutrient cycling, and the partitioning between aboveground and belowground allocation of carbon. Here we experimentally tested how moose (Alces alces) at different simulated population densities affected belowground respiration rates (estimated as CO(2) flux) in young boreal forest stands situated along a site productivity gradient. At high simulated population density, moose browsing considerably depressed belowground respiration rates (24-56% below that of no-moose controls) except during June, where the difference only was 10%. Moose browsing depressed belowground respiration the most on low-productivity sites. Soil moisture and temperature did not affect respiration rates. Impact of moose on belowground respiration was closely linked to litter production and followed Michaelis-Menten dynamics. The main mechanism by which moose decrease belowground respiration rates is likely their effect on photosynthetic biomass (especially decreased productivity of deciduous trees) and total litter production. An increased productivity of deciduous trees along the site productivity gradient causes an unequal effect of moose along the same gradient. The rapid growth of deciduous trees may offer higher resilience against negative effects of moose browsing on litter production and photosynthate allocation to roots.
Alces alces; autotrophic respiration; boreal forest; carbon cycling; CO(2) efflux; habitat productivity; heterotrophic respiration; large herbivores; litterfall; moose; soil respiration; Sweden
2009, Volym: 90, nummer: 10, sidor: 2724-2733
Environmental Sciences related to Agriculture and Land-use