Holocene wildfire regimes in forested peatlands in western Siberia: interaction between peatland moisture conditions and the composition of plant functional types

Wildfire is the most common disturbance type inboreal forests and can trigger significant changes in forestcomposition. Waterlogging in peatlands determines the degree of tree cover and the depth of the burnt horizon associated with wildfires. However, interactions between peatland moisture, vegetation composition and flammability, andfire regime in forest and forested peatland in Eurasia remain largely unexplored, despite their huge extent in borealregions. To address this knowledge gap, we reconstructedthe Holocene fire regime, vegetation composition, and peatland hydrology at two sites located in predominantly lighttaiga (Pinus sylvestris Betula) with interspersed dark taigacommunities (Pinus sibirica, Picea obovata, Abies sibirica)in western Siberia in the Tomsk Oblast, Russia. We foundmarked shifts in past water levels over the Holocene. Theprobability of fire occurrence and the intensification of firefrequency and severity increased at times of low water table(drier conditions), enhanced fuel dryness, and an intermediate dark-to-light taiga ratio. High water level, and thus wetpeat surface conditions, prevented fires from spreading onpeatland and surrounding forests. Deciduous trees (i.e. Betula) and Sphagnum were more abundant under wetter peatland conditions, and conifers and denser forests were moreprevalent under drier peatland conditions. On a Holocenescale, severe fires were recorded between 7.5 and 4.5 ka withan increased proportion of dark taiga and fire avoiders (Pinussibirica at Rybnaya and Abies sibirica at Ulukh–Chayakh)in a predominantly light taiga and fire-resister communitycharacterised by Pinus sylvestris and lower local water level.Severe fires also occurred over the last 1.5 kyr and were associated with a declining abundance of dark taiga and fireavoiders, an expansion of fire invaders (Betula), and fluctuating water tables. These findings suggest that frequent,high-severity fires can lead to compositional and structuralchanges in forests when trees fail to reach reproductive maturity between fire events or where extensive forest gaps limitseed dispersal. This study also shows prolonged periods ofsynchronous fire activity across the sites, particularly duringthe early to mid-Holocene, suggesting a regional imprint ofcentennial- to millennial-scale Holocene climate variabilityon wildfire activity. Humans may have affected vegetationand fire from the Neolithic; however, increasing human presence in the region, particularly at the Ulukh–Chayakh Mireover the last 4 centuries, drastically enhanced ignitions compared to natural background levels. Frequent warm and dryspells predicted by climate change scenarios for Siberia inthe future will enhance peatland drying and may convey acompetitive advantage to conifer taxa. However, dry conditions will probably exacerbate the frequency and severityof wildfire, disrupt conifers’ successional pathway, and accelerate shifts towards deciduous broadleaf tree cover. Furthermore, climate–disturbance–fire feedbacks will acceleratechanges in the carbon balance of boreal peatlands and affecttheir overall future resilience to climate chang

Holocene wildfire regimes in western Siberia: interaction between peatland moisture conditions and the composition of plant functional types

Wildfire is the most common disturbance type in boreal forests and can trigger significant changes in forest composition. Waterlogging in peatlands determines the degree of tree cover and the depth of the burnt horizon associated with wildfires. However, interactions between peatland moisture, vegetation composition and flammability, and fire regime in forest and forested peatland in Eurasia remain largely unexplored, despite their huge extent in boreal regions. To address this knowledge gap, we reconstructed the Holocene fire regime, vegetation composition, and peatland hydrology at two sites located in predominantly light taiga (Pinus sylvestris Betula) with interspersed dark taiga communities (Pinus sibirica, Picea obovata, Abies sibirica) in western Siberia in the Tomsk Oblast, Russia. We found marked shifts in past water levels over the Holocene. The probability of fire occurrence and the intensification of fire frequency and severity increased at times of low water table (drier conditions), enhanced fuel dryness, and an intermediate dark-to-light taiga ratio. High water level, and thus wet peat surface conditions, prevented fires from spreading on peatland and surrounding forests. Deciduous trees (i.e. Betula) and Sphagnum were more abundant under wetter peatland conditions, and conifers and denser forests were more prevalent under drier peatland conditions. On a Holocene scale, severe fires were recorded between 7.5 and 4.5 ka with an increased proportion of dark taiga and fire avoiders (Pinus sibirica at Rybnaya and Abies sibirica at Ulukh-Chayakh) in a predominantly light taiga and fire-resister community characterised by Pinus sylvestris and lower local water level. Severe fires also occurred over the last 1.5 kyr and were associated with a declining abundance of dark taiga and fire avoiders, an expansion of fire invaders (Betula), and fluctuating water tables. These findings suggest that frequent, high-severity fires can lead to compositional and structural changes in forests when trees fail to reach reproductive maturity between fire events or where extensive forest gaps limit seed dispersal. This study also shows prolonged periods of synchronous fire activity across the sites, particularly during the early to mid-Holocene, suggesting a regional imprint of centennial-to millennial-scale Holocene climate variability on wildfire activity. Humans may have affected vegetation and fire from the Neolithic; however, increasing human presence in the region, particularly at the Ulukh-Chayakh Mire over the last 4 centuries, drastically enhanced ignitions compared to natural background levels. Frequent warm and dry spells predicted by climate change scenarios for Siberia in the future will enhance peatland drying and may convey a competitive advantage to conifer taxa. However, dry conditions will probably exacerbate the frequency and severity of wildfire, disrupt conifers' successional pathway, and accelerate shifts towards deciduous broadleaf tree cover. Furthermore, climate-disturbance-fire feedbacks will accelerate changes in the carbon balance of boreal peatlands and affect their overall future resilience to climate change