Abstract
Invasive insect pests are a common disturbance in temperate forests, but their effects on belowground processes in these ecosystems are poorly understood. This study examined how aboveground disturbance might impact short-term soil carbon flux in a forest impacted by emerald ash borer (Agrilus planipennis Fairmaire) in central New Hampshire, USA. We anticipated changes to soil moisture and temperature resulting from tree mortality caused by emerald ash borer, with subsequent effects on rates of soil respiration and methane oxidation. We measured carbon dioxide emissions and methane uptake beneath trees before, during, and after infestation by emerald ash borer. In our study, emerald ash borer damage to nearby trees did not alter soil microclimate nor soil carbon fluxes. While surprising, the lack of change in soil microclimate conditions may have been a result of the sandy, well-drained soil in our study area and the diffuse spatial distribution of canopy ash trees and subsequent canopy light gaps after tree mortality. Overall, our results indicate that short-term changes in soil carbon flux following insect disturbances may be minimal, particularly in forests with well-drained soils and a mixed-species canopy.
Highlights
Invasive forest insects can create biotic disturbances that critically alter ecosystem processes and ecosystem services [1,2,3]
This study examined the short-term, two-year impact of the invasive emerald ash borer (EAB; Agrilus planipennis Fairmaire) on soil carbon dioxide (CO2 ) and methane (CH4 ) fluxes shortly following the first detection of EAB in a mixed deciduous forest in New Hampshire, USA
As biotic disturbances become more common in temperate forests [63], there is a need to understand the consequences of these events for ecosystem carbon dynamics
Summary
Invasive forest insects can create biotic disturbances that critically alter ecosystem processes and ecosystem services [1,2,3]. Many invasive insects cause tree stress and mortality through wood-boring, phloem-feeding, or defoliation, which potentially changes plant carbon and nutrient allocation strategies and subsequent plant-soil feedbacks [6,7]. This study examined the short-term, two-year impact of the invasive emerald ash borer (EAB; Agrilus planipennis Fairmaire) on soil carbon dioxide (CO2 ) and methane (CH4 ) fluxes shortly following the first detection of EAB in a mixed deciduous forest in New Hampshire, USA. EAB is an invasive wood-boring insect that kills trees of the genus Fraxinus by effectively girdling stem xylem tissue with larval feeding tunnels [8]. Mortality in Fraxinus trees infested with EAB is rapid and trees generally die 1–2 years after EAB activity is detected [9,10,11]. There are several management strategies under consideration, including preemptive and salvage logging, insecticide, and biological control; none of these have been effective in slowing the spread of EAB [13]
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