Back to Search Start Over

Impact of post-fire management on soil respiration, carbon and nitrogen content in a managed hemiboreal forest.

Authors :
Parro, Kristi
Köster, Kajar
Jõgiste, Kalev
Seglinš, Katrin
Sims, Allan
Stanturf, John A.
Metslaid, Marek
Source :
Journal of Environmental Management. Mar2019, Vol. 233, p371-377. 7p.
Publication Year :
2019

Abstract

Abstract Boreal forests are an important carbon (C) sink and fire is the main natural disturbance, directly affecting the C-cycle via emissions from combustion of biomass and organic matter and indirectly through long-term changes in C-dynamics including soil respiration. Carbon dioxide (CO 2) emission from soil (soil respiration) is one of the largest fluxes in the global C-cycle. Recovery of vegetation, organic matter and soil respiration may be influenced by the intensity of post-fire management such as salvage logging. To study the impact of forest fire, fire and salvage, and recovery time on soil respiration and soil C and N content, we sampled two permanent research areas in north-western Estonia that were damaged by fire: Vihterpalu (59°13′ N 23°49′ E) in 1992 and Nõva (59°10′ N 23°45′ E) in 2008. Three types of sample plots were established: 1) unburned control with no harvesting (CO); 2) burned and uncleared (BU); and 3) burned and cleared (BC). Measurements were made in 2013, 21 years after wildfire in Vihterpalu and 5 years after wildfire in Nõva. Soil respiration ranged from 0.00 to 1.38 g CO 2 m−2 h−1. Soil respiration in the burned and cleared areas (BC) was not reduced compared to burned and uncleared (BU) areas but the average soil respiration in unburned control areas was more than twice the value in burned areas (average soil respiration in CO areas was 0.34 CO 2 m−2 h−1, versus 0.16 CO 2 m−2 h−1, the average soil respiration of BC and BU combined). Recovery over 20 years was mixed; respiration was insignificantly lower on younger than older burned sites (when BC and BU values were combined, the average values were 0.15 vs. 0.17 g CO 2 m−2 h−1, respectively); soil-C was greater in the older burned plots than the younger (when BC and BU values were combined, the average values were 9.71 vs. 5.99 kg m−2, respectively); but root biomass in older and recently burned areas was essentially the same (average 2.23 and 2.11 kg m−2, respectively); soil-N was highest on burned areas 20 years after fire. Twenty years post-fire may be insufficient time for carbon dynamics to fully recover on these low productivity sandy sites. Highlights • 20 years post-burning was insufficient for soil respiration recovery on sandy soils. • Soil respiration in burned areas was not reduced further by salvage logging. • Soil carbon may be restored to unburned levels in 20 years. • Salvage logging on burned areas decreases the rate of recovery of soil carbon. • Soil nitrogen recovered in 20 years but was not correlated with respiration. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
03014797
Volume :
233
Database :
Academic Search Index
Journal :
Journal of Environmental Management
Publication Type :
Academic Journal
Accession number :
134253187
Full Text :
https://doi.org/10.1016/j.jenvman.2018.12.050