Martin P. Girardin, Dorian Gaboriau, Adam A. Ali, Konrad Gajewski, Michelle Brière, Yves Bergeron, Jordan Paillard, Justin Waito, Jacques Tardif. Boreal forest cover was reduced in the mid-Holocene with warming and recurring wildfires 2024. Commun Earth Environ 176
DOI : 10.1038/s43247-024-01340-8
The hemi-boreal zone, marking North America’s southern boreal forest boundary, has evolved post-glaciation, hosting diverse ecosystems including mixed forests with savannas, grasslands, and wetlands. While human, climate, and fire interactions shape vegetation dynamics therein, specific influences remain unclear. Here we unveil 12,000 years of hemi-boreal zone dynamics, exploring wildfire, vegetation, climate, and human population size interactions at such long time scales. Postglacial biomass burning exhibited episodes of persistent elevated activity, and a pivotal shift around 7000 years ago saw the boreal forest transition to an oak-pine barren ecosystem for about 2000 years before reverting. This mid-Holocene shift occurred during a period of more frequent burning and a sudden uptick in mean annual temperatures. Population size of Indigenous peoples mirrored wildfire fluctuations, decreasing with more frequent burning. Anticipated increases of fire activity with climate change are expected to echo transformations observed 7000 years ago, reducing boreal forest extent, and impacting land use.
Marianne Vogel, Adam A. Ali, Sébastien Joannin, Yves Bergeron, Hugo Asselin. Postglacial vegetation migration facilitated by outposts on proglacial lake islands in eastern North America 2024. Quaternary Science Advances 100164
DOI : 10.1016/j.qsa.2024.100164
Postglacial vegetation colonization that followed ice retreat and proglacial lakes drainage in north-eastern America occurred rapidly, more rapidly than expected based on the modern dispersal capacities of boreal mixedwood trees. Paleo-islands from proglacial Lake Ojibway in Québec (Canada) were afforested early, before the final drainage of the lake. We hypothesized that these paleo-islands could have acted as outposts of migration and thus, could explain the rapid afforestation of lowlands observed. To determine if postglacial colonization occurred as a south-north front from the southern margin of Lake Ojibway or if islands acted as migration outposts, we estimated the date of first arrival of the main taxa of the current boreal mixedwood forest. We studied southern sites never covered by proglacial Lake Ojibway, sites that were islands within Lake Ojibway, and northern lowland sites that were liberated after the final drainage of proglacial Lake Ojibway. Taxa arrival was estimated as a sharp rise of the pollen percentage or as the occurrence of macro-remains within the sediments of small lakes dated with radiocarbon. Then we compared migration scenarios where colonization occurred gradually from south to north from the southern margin of proglacial Lake Ojibway and where paleo-islands of Lake Ojibway were first colonized through long-distance dispersal, thus becoming sources of seeds readily available to colonize lowland sites after the final drainage of Lake Ojibway. Finally, we compared the migration rates from the scenarios with the current mean dispersal capacities of the studied taxa. The migration rates estimated without taking the paleo-islands into account are too slow to explain the rapid afforestation observed following the final drainage of proglacial Lake Ojibway. Only the migration rates estimated from the scenarios with paleo-islands were comparable to the current mean dispersal capacity of the boreal mixedwood taxa. Thus, paleo-islands acted as stepping stones during postglacial migration, which explains why the lowlands were rapidly colonized. Larger paleo-islands and those located closer to the southern margin of the proglacial Lake were colonized first, in line with the theory of island biogeography.
Augustin Feussom, Laurent Millet, Damien Rius, Adam A. Ali, Yves Bergeron, Pierre Grondin, Sylvie Gauthier, Olivier Blarquez. An 8500-year history of climate-fire-vegetation interactions in the eastern maritime black spruce–moss bioclimatic domain, Québec, Canada 2023. Ecoscience 1
DOI : 10.1080/11956860.2023.2292354
The eastern, maritime portion of the black spruce – moss bioclimatic domain in Québec (Canada) is characterized by large wildfires with low occurrence. However, it is still poorly understood how climate–fire interactions influenced long-term vegetation dynamics in the boreal forest of eastern Québec. The long-term historical climate–fire–vegetation interactions in this region were investigated using a multiproxy (chironomids, charcoal, and pollen) paleoecological analysis of an 8500-year sediment core. Chironomid-inferred August air temperatures suggest that the warm Holocene Thermal Maximum (HTM; between ca. 7000–4000 cal yr BP) shifted to the cooler Neoglacial period (4000 cal yr BP to present), consistent with other temperature reconstructions across Québec. The shift to spruce-moss forest dominance around 4800 cal yr BP occurred nearly a thousand years before the climatic shift to the Neoglacial period and rather coincided with a shift from frequent low-severity small fires to infrequent but large and severe fire events. Our results suggest that long-term changes in the summer temperature are probably not the main factor controlling fire and vegetation dynamics in eastern Québec. It seems that, throughout the postglacial period, summer temperatures never fell below a threshold that could have induced a significant vegetation response.
La partie orientale et maritime du domaine bioclimatique de la pessière à mousse au Québec (Canada), est caractérisée par des grands incendies à très faible occurrence. Cependant, l’effet des interactions climat-feu sur la dynamique à long terme de la végétation dans la forêt boréale de l’est du Québec est peu connu. A l’aide d’une analyse paléoécologique multiproxies (chironomes, charbon de bois, pollen) d’une carotte sédimentaire de 8500 ans, nous avons documenté les interactions à long terme entre le climat, le feu et la végétation à l’est du Québec. Les températures de l’air du mois d’août reconstituées par les chironomes suggèrent que la période chaude de l’Optimum climatique Holocène (7000-4000 ans avant aujourd’hui (AA)) a cédé place à la période froide du Néoglaciaire (4000 ans AA à l’actuel) en cohérence avec les reconstitutions climatiques réalisées ailleurs au Québec. L’établissement de la pessière à mousses il y a environ 4800 ans s’est produit près d’un millier d’années avant la transition vers le Néoglaciaire et a plutôt coïncidé avec le changement de petits incendies peu sévères fréquents, à de grands incendies sévères peu fréquents. D’après nos résultats, les changements de températures estivales ne semblent pas jouer un rôle prépondérant dans la dynamique de la végétation et des feux dans l’est du Québec. Il semble que, tout au long de la période postglaciaire, les températures estivales n’aient jamais diminué sous un seuil qui aurait induit une réponse significative de la végétation.
Tuomas Aakala, Cécile C. Remy, Dominique Arseneault, Hubert Morin, Martin-Philippe Girardin, Fabio Gennaretti, Lionel Navarro, Niina Kuosmanen, Adam A. Ali, Étienne Boucher, Normunds Stivrins, Heikki Seppä, Yves Bergeron, Miguel Montoro Girona. Millennial-Scale Disturbance History of the Boreal Zone 2023. In: Girona, M.M., Morin, H., Gauthier, S., Bergeron, Y. (eds) Boreal Forests in the Face of Climate Change. Advances in Global Change Research, vol 74. Springer, Cham. 53
DOI : 10.1007/978-3-031-15988-6_2
Long-term disturbance histories, reconstructed using diverse paleoecological tools, provide high-quality information about pre-observational periods. These data offer a portrait of past environmental variability for understanding the long-term patterns in climate and disturbance regimes and the forest ecosystem response to these changes. Paleoenvironmental records also provide a longer-term context against which current anthropogenic-related environmental changes can be evaluated. Records of the long-term interactions between disturbances, vegetation, and climate help guide forest management practices that aim to mirror “natural” disturbance regimes. In this chapter, we outline how paleoecologists obtain these long-term data sets and extract paleoenvironmental information from a range of sources. We demonstrate how the reconstruction of key disturbances in the boreal forest, such as fire and insect outbreaks, provides critical long-term views of disturbance-climate-vegetation interactions. Recent developments of novel proxies are highlighted to illustrate advances in reconstructing millennial-scale disturbance-related dynamics and how this new information benefits the sustainable management of boreal forests in a rapidly changing climate.
Marion Lacand, Hugo Asselin, Gwenaël Magne, Tuomas Aakala, Cécile C. Remy, Heikki Seppä, Adam A. Ali. Multimillennial fire history of northern Finland along a latitude/elevation gradient. 2023. Quaternary Research 108171
DOI : 10.1016/j.quascirev.2023.108171
In boreal environments, wildfires are expected to decrease in frequency and/or size with latitude/elevation, mainly in response to climate, as well as fuel availability and type. Furthermore, fire frequency and biomass burned are supposed to have been higher during warm and dry periods of the Holocene (last ∼ 11,000 years). We tested these assumptions in northern Finland by using charcoal analysis to reconstruct Holocene regional fire regimes from eight lake sediment sequences sampled within four different environments in terms of elevation, latitude and vegetation type: (1) low latitude/mid elevation coniferous forests (Pinus sylvestris and Picea abies); (2) mid latitude/low elevation pine forests (Pinus sylvestris); (3) mid
Marianne Vogel, Hugo Asselin, Sébastien Joannin, Yves Bergeron, Sabrina Leclercq, Cécile Latapy, Adam A. Ali. Early afforestation on islands of proglacial Lake Ojibway as evidence of post-glacial migration outposts. 2023. Holocene 975-985
DOI : 10.1177/09596836231169988
At the end of the last glacial period in the northern hemisphere, meltwater from receding ice sheets accumulated into large proglacial lakes, potentially limiting postglacial afforestation. We explored whether former islands of proglacial Lake Ojibway (Canada) (hilltops in the current landscape) could have acted as migration outposts and thus accelerated the postglacial migration. We extracted sediments from two small lakes located on “paleo-islands” and used XRF to detect changes in soil erosion and vegetation biomass. We also used plant macro-remains and wood charcoal to determine if (and which) tree species colonized the sites and to detect local fire events. Organic sediment accumulation started around 9657 and 9947 cal. yr BP at Lakes Perché and Despériers, respectively, before the level of Lake Ojibway started to decrease and liberate parts of the studied landscape ca 9400 cal. yr BP. Lithogenic elements (Ti, K, Sr, Fe, Zr, and Rb) decreased between the beginning of organic sediment accumulation and 8800–8700 cal. yr BP, indicating reduced soil erosion, possibly due to soil stabilization by vegetation. Then, the S/Ti ratio, a proxy of organic matter increased around 8800 and 8400 cal. yr BP. The earliest tree macro-remains (Larix laricina and Pinus spp.) were found between 9850 and 9500 cal. yr BP. Local fires were detected around 9820 and 8362 cal. yr BP. Early afforestation occurred on the islands of Lake Ojibway, 200 and 450 years before its level started to decrease, confirming that some islands acted as migratory outposts accelerating postglacial migration.
Dorian Gaboriau, Emeline Chaste, Martin-Philippe Girardin, Hugo Asselin, Adam A. Ali, Yves Bergeron, Christelle Hely-Alleaume. Interactions within the climate-vegetation-fire nexus may transform 21st century boreal forests in northwestern Canada. 2023. iScience 26:106807
DOI : 10.1016/j.isci.2023.106807
Dry and warm conditions have exacerbated the occurrence of large and severe wildfires over the past decade in Canada’s Northwest Territories (NT). While temperatures are expected to increase during the 21st century, we lack understanding of how the climate-vegetation-fire nexus might respond. We used a dynamic global vegetation model to project annual burn rates, as well as tree species composition and biomass in the NT during the 21st century using the IPCC’s climate scenarios. Burn rates will decrease in most of the NT by the mid-21st century, concomitant with biomass loss of fire-prone evergreen needleleaf tree species, and biomass increase of broadleaf tree species. The southeastern NT is projected to experience enhanced fire activity by the late 21st century according to scenario RCP4.5, supported by a higher production of flammable evergreen needleleaf biomass. The results underlie the potential for major impacts of climate change on the NT’s terrestrial ecosystems.
Cécile C. Remy, Gwenaël Magne, Normunds Stivrins, Tuomas Aakala, Hugo Asselin, Heikki Seppä, Tomi Luoto, Nauris Jasiunas, Adam A. Ali. Climatic and vegetational controls of Holocene wildfire regimes in the boreal forest of northern Fennoscandia. 2023. Journal of Ecology 111(4):845-860
DOI : 10.1111/1365-2745.14065
Abstract Climate change is expected to increase wildfire activity in boreal ecosystems, thus threatening the carbon stocks of these forests, which are currently the largest terrestrial carbon sink in the world. Describing the ecological processes involved in fire regimes in terms of frequency, size, type (surface vs. crown) and severity (biomass burned) would allow better anticipation of the impact of climate change on these forests. In Fennoscandia, this objective is currently difficult to achieve due to the lack of knowledge of long-term (centuries to millennia) relationships between climate, fire and vegetation. We investigated the causes and consequences of changes in fire regimes during the Holocene (last ~11,000 years) on vegetation trajectories in the boreal forest of northern Finland. We reconstructed fire histories from sedimentary charcoal at three sites, as well as vegetation dynamics from pollen, moisture changes from Sphagnum spore abundance at two sites, and complemented these analyses with published regional chironomid-inferred July temperature reconstructions. Low-frequency, large fires were recorded during the warm and dry mid-Holocene period (8500–4500 cal. year BP), whereas high-frequency, small fires were more characteristic of the cool and wet Neoglacial period (4500 cal. year BP onward). A higher proportion of charcoal particles with a woody aspect—characterizing crown fires—was recorded at one of the two sites at times of significant climatic and vegetational changes, when the abundance of Picea abies was higher. Synthesis. Our results show both a direct and an indirect effect of climate on fire regimes in northern Fennoscandia. Warm and dry periods are conducive to large surface fires, whereas cool and moist periods are associated with small fires, either crown or surface. Climate-induced shifts in forest composition also affect fire regimes. Climatic instability can alter vegetation composition and structure and lead to fuel accumulation favouring stand-replacing crown fires. Considering the ongoing climate warming and the projected increase in extreme climatic events, Fennoscandian forests could experience a return to a regime of large surface fires, but stand-replacing crown fires will likely remain a key ecosystem process in areas affected by climatic and/or vegetational instability.
Nina Ryzhkova, Alexander Kryshen, Mats Niklasson, Guilherme Pinto, A. Aleinikov, I. Kutyavin, Yves Bergeron, Adam A. Ali, Igor Drobyshev. Climate drove the fire cycle and humans influenced fire
occurrence in the East European boreal forest. 2022. Ecological Monographs 92(4): e1530
DOI : 10.1002/ecm.1530
Understanding long-term forest fire histories of boreal landscapes is instrumental for parameterizing climate–fire interactions and the role of humans affecting natural fire regimes. The eastern sections of the European boreal zone currently lack a network of annually resolved and centuries-long forest fire histories. To fill in this knowledge gap, we dendrochronologically reconstructed the 600-year fire history of a middle boreal pine-dominated landscape of the southern part of the Republic of Komi, Russia. We combined the reconstruction of fire cycle (FC) and fire occurrence with the data on the village establishment and climate proxies and discussed the relative contribution of climate versus human land use in shaping historic fire regimes. Over the 1340–1610 ce period, the territory had a FC of 66 years (with the 90% confidence envelope of 56.8 and 78.6 years). Fire activity increased during the 1620–1730 ce period, with the FC reaching 32 years (31.0–34.7 years). Between 1740–1950, the FC increased to 47 years (41.9–52.0). The most recent period, 1960–2010, marks FC's historic maximum, with the mean of 153 years (102.5–270.3). Establishment of the villages, often as small harbors on the Pechora River, was associated with a non-significant increase in fire occurrence in the sites nearest the villages (p = 0.07–0.20). We, however, observed a temporal association between village establishment and fire occurrence at the scale of the whole studied landscape. There was no positive association between the former and the FC. In fact, we documented a decline in the area burned, following the wave of village establishment during the second half of the 1600s and the first half of the 1700s. The lack of association between the dynamics of FC and the dates of village establishments, and the significant association between large fire years and the early and latewood pine chronologies, used as historic drought proxy, indirectly suggests that the climate was the primary control of the landscape-level FCs in the studied forests. Pine-dominated forests of the Komi Republic may hold a unique position as the ecosystem with the shortest history of human-related shifts in fire cycles across the European boreal region.
Dorian Gaboriau, Adam A. Ali, Christelle Hely-Alleaume, Hugo Asselin, Martin-Philippe Girardin. Drivers of extreme wildfire years in the 1965–2019 fire regime of the Tłı̨chǫ First Nation territory, Canada 2022. Ecoscience 29(3):249-265
DOI : 10.1080/11956860.2022.2070342
Exceptionally large areas burned in 2014 in central Northwest Territories (Canada), leading members of the Tłı̨chǫ First Nation to characterize this year as ‘extreme’. Top-down climatic and bottom-up environmental drivers of fire behavior and areas burned in the boreal forest are relatively well understood, but not the drivers of extreme wildfire years (EWY). We investigated the temporal and spatial distributions of fire regime components (fire occurrence, size, cause, fire season length) on the Tłı̨chǫ territory from 1965 to 2019. We used BioSIM and data from weather stations to interpolate mean weather conditions, fuel moisture content and fire-weather indices for each fire season, and we described the environmental characteristics of burned areas. We identified and characterized EWY, i.e., years exceeding the 80th percentile of annual area burned for the study period. Temperature and fuel moisture were the main drivers of areas burned. Nine EWY occurred from 1965 to 2019, including 2014. Compared to non-EWY, EWY had significantly higher mean temperature (>14.7°C) and exceeded threshold values of Drought Code (>514), Initial Spread Index (>7), and Fire Weather Index (>19). Our results will help limit the effects of EWY on human safety, health and Indigenous livelihoods and lifestyles.
Sandy P. Harrison, Roberto Villegas-Diaz, Esmeralda Cruz-Silva, Daniel Gallagher, David Kesner, Paul Lincoln, Yicheng Shen, Luke Sweeney, Daniele Colombaroli, Adam A. Ali, Chéïma Barhoumi , Yves Bergeron, Tatiana Blyakharchuk, Přemysl Bobek, R.H.W. Bradshaw, Jennifer L. Clear, Sambor Czerwiński, Anne-Laure Daniau, John Dodson, Kevin J. Edwards, M.E. Edwards, A. Feurdean, D. Foster, Konrad Gajewski, M. Gałka, Michelle Garneau, T. Giesecke, G. Gil Romera, Martin-Philippe Girardin, D. Hoefer, K. Huang, J. Inoue, E. Jamrichová, N. Jasiunas, W. Jiang, G. Jiménez-Moreno, M. Karpińska-Kołaczek, P. Kołaczek, N. Kuosmanen, Mariusz Lamentowicz, Martin Lavoie, F. Li, J. Li, O. Lisitsyna, J.A. López-Sáez, R. Luelmo-Lautenschlaeger, Gabriel Magnan, E.K. Magyari, A. Maksims, K. Marcisz, E. Marinova, J. Marlon, S. Mensing, J. Miroslaw-Grabowska, W. Oswald, S. Pérez-Dı́az, R. Pérez-Obiol, S. Piilo, A. Poska, X. Qin, Cécile C. Remy, Pierre J.H. Richard, S. Salonen, N. Sasaki, H. Schneider, W. Shotyk, M. Stancikaite, D. Šteinberga, N. Stivrins, H. Takahara, Z. Tan, L. Trasune, C.E. Umbanhowar, M. Väliranta, J. Vassiljev, X. Xiao, Q. Xu, X. Xu, E. Zawisza, Y. Zhao, Z. Zhou, Jordan Paillard. The Reading Palaeofire Database: an expanded global resource to document changes in fire regimes from sedimentary charcoal records. 2022. Earth Syst. Sci. Data 14:1109-1124
DOI : 10.5194/essd-14-1109-2022
Sedimentary charcoal records are widely used to reconstruct regional changes in fire regimes through time in the geological past. Existing global compilations are not geographically comprehensive and do not provide consistent metadata for all sites. Furthermore, the age models provided for these records are not harmonised and many are based on older calibrations of the radiocarbon ages. These issues limit the use of existing compilations for research into past fire regimes. Here, we present an expanded database of charcoal records, accompanied by new age models based on recalibration of radiocarbon ages using IntCal20 and Bayesian age-modelling software. We document the structure and contents of the database, the construction of the age models, and the quality control measures applied. We also record the expansion of geographical coverage relative to previous charcoal compilations and the expansion of metadata that can be used to inform analyses. This first version of the Reading Palaeofire Database contains 1676 records (entities) from 1480 sites worldwide. The database (RPDv1b – Harrison et al., 2021) is available at https://doi.org/10.17864/1947.000345.
Chéïma Barhoumi , Adam A. Ali, Odile Peyron , L Dugergil , O Borisova , G Subetto , Alexander Kryshen, Igor Drobyshev, Nina Ryzhkova. Did long-term fire control the coniferous boreal forest composition of northern Ural region 2020. J. of Biogeography 2426-2441
DOI : 10.1111/jbi.13922
Dorian Gaboriau, Yves Bergeron, Cécile C. Remy, Adam A. Ali, Christelle Hely-Alleaume, Martin-Philippe Girardin, Hugo Asselin. Temperature and fuel availability control fire size/severity in the
boreal forest of central Northwest Territories, Canada. 2020. Quaternary Science Review 250:106697
DOI : 10.1016/j.quascirev.2020.106697
The north-central Canadian boreal forest experienced increased occurrence of large and severe wildfires caused by unusually warm temperatures and drought events during the last decade. It is, however, difficult to assess the exceptional nature of this recent wildfire activity, as few long-term records are available in the area. We analyzed macroscopic sedimentary charcoal from four lakes and pollen grains from one of those lakes to reconstruct long-term fire regimes and vegetation histories in the boreal forest of central Northwest Territories. We used regional estimates of past temperature and hydrological changes to identify the climatic drivers of fire activity over the past 10,000 years. Fires were larger and more severe during warm periods (before ca. 5000 cal yrs. BP and during the last 500 years) and when the forest landscape was characterized by high fuel abundance, especially fire-prone spruce. In contrast, colder conditions combined with landscape opening (i.e., lower fuel abundance) during the Neoglacial (after ca. 5000 cal yrs. BP) were related with a decline in fire size and severity. Fire size and severity increased during the last five centuries, but remained within the Holocene range of variability. According to climatic projections, fire size and severity will likely continue to increase in central Northwest Territories in response to warmer conditions, but precipitation variability, combined with increased abundance of deciduous species or opening of the landscape, could limit fire risk in the future.
Gwenaël Magne, Benoit Brossier, Emmanuel Gandouin, Laure Paradis, Alexander Kryshen, Samuel Alleaume, Adam A. Ali, Igor Drobyshev, Christelle Hely-Alleaume. Lacustrine charcoal peaks provide an accurate record of surface wildfires in a North European boreal forest. 2020. Holocene 30(3):380-388
DOI : 10.1177/0959683619887420
We evaluated the skills of different palaeofire reconstruction techniques to reconstruct the fire history of a boreal landscape (Russian Karelia) affected by surface fires. The analysis of dated lacustrine sediments from two nearby lakes was compared with independent dendrochronological dating of fire scars, methods which have rarely been used in context of surface fires. We used two sediment sub-sampling volumes (1 and 3.5 cm3, wet volumes) and three methods of calculating the Charcoal Accumulation Rate to reconstruct fire histories: CHAR number, charcoal surface area and estimated charcoal volume. The results show that palaeofire reconstructions obtained with fossil charcoal data from lake sediments and dendrochronology are similar and complementary. Dendrochronological reconstruction of fire scars established 12 fire dates over the past 500 years, and paleo-data from lake sediments identified between 7 and 13 fire events. Several ‘false fire events’ were also recorded in the charcoal chronologies, likely because of errors associated with the estimation of the sediment accumulation rate in the unconsolidated part of the sediment. The number of replicates, that is, number of sub-samples and lakes analyzed, had an effect on the number of identified fire events, whereas no effect was seen in the variation in the analyzed sediment volume or the choice of the charcoal-based metric. Whenever possible, we suggest the use of the dendrochronological data as an independent control for the calibration of charcoal peak series, which helps provide more realistic millennia-long reconstruction of past fire activity. We also argue for the use of 1 cm3 sample volume, a sampling protocol involving sampling of more than one lake, and sufficient number of intra-sample replicates to achieve skilful reconstructions of past fire activity.
Emeline Chaste, Yves Bergeron, Olivier Blarquez, Cécile C. Remy, Martin-Philippe Girardin, Adam A. Ali, Christelle Hely-Alleaume. A Holocene Perspective of Vegetation Controls on Seasonal Boreal Wildfire Sizes Using Numerical Paleo-Ecology. 2020. Frontiers in ecology and the environment 3:106
DOI : 10.3389/ffgc.2020.511901
Wildland fire is the most important disturbance in the boreal forests of eastern North America, shaping the floral composition, structure and spatial arrangement. Although the long-term evolution of the frequency and quantity of burned biomass in these forests can be estimated from paleo-ecological studies, we know little about the evolution of fire sizes. We have therefore developed a methodological approach that provides insights into the processes and changes involved over time in the historical fire-vegetation-climate environment of the coniferous forests (CF) and mixedwood forests (MF) of eastern boreal North America, paying particular attention to the metric of fire size. Lacustrine charcoal particles sequestered in sediments from MF and CF regions were analyzed to reconstruct changes in estimated burned biomass, fire frequency, and their ratio interpreted as fire size (FS-index), over the last 7,000 years. A fire propagation model was used to simulate past fire sizes using both a reference landscape, where MF and CF compositions over time were prescribed using pollen reconstructions, and climate inputs provided by the HadCM3BL-M1 snapshot simulations. Lacustrine charcoals showed that Holocene FS-indices did not differ significantly between MF and CF because of the high variability in fire frequencies. However, the estimated burned biomass from MF was always lower than that from CF, significantly so since 5,000 BP. Beyond the variability, the FS-index was lower in MF than CF throughout the Holocene, with slight changes in both forests from 7,000 to 1,000 BP, and simultaneous increases over the last millennium. The fire model showed that MF fires were consistently smaller than CF fires throughout the Holocene, with larger differences in the past than today. The fire model also highlighted the fact that spring fires in both forest types have always been larger than summer fires over the last 7,000 years, which concurs with present-day fire statistics. This study illustrates how fire models, built and used today for forecasting and firefighting, can also be used to enhance our understanding of past conditions within the fire-vegetation-climate nexus.
Julie C. Aleman, Andy Hennebelle, Yves Bergeron, Adam A. Ali, Christopher Carcaillet, Josianne Landry, Olivier Blarquez, Pierre Grondin. The reconstruction of burned area
and fire severity using charcoal
from boreal lake sediments. 2020. Holocene 30(10):1400-1409
DOI : 10.1177/0959683620932979
Although lacustrine sedimentary charcoal has long been used to infer paleofires, their quantitative reconstructions require improvements of the calibration of their links with fire regimes (i.e. occurrence, area, and severity) and the taphonomic processes that affect charcoal particles between the production and the deposition in lake sediments. Charcoal particles >150?µm were monitored yearly from 2011 to 2016 using traps submerged in seven head lakes situated in flat-to-rolling boreal forest landscapes in eastern Canada. The burned area was measured, and the above-ground fire severity was assessed using the differentiated normalized burn ratio (dNBR) index, derived from LANDSAT images, and measurements taken within zones radiating 3, 15, and 30?km from the lakes. In order to evaluate potential lag effects in the charcoal record, fire metrics were assessed for the year of recorded charcoal recording (lag 0) and up to 5?years before charcoal deposition (lag 5). A total of 92 variables were generated and sorted using a Random Forest-based methodology. The most explanatory variables for annual charcoal particle presence, expressed as the median surface area, were selected. Results show that, temporally, sedimentary charcoal accurately recorded fire events without a temporal lag; spatially, fires were recorded up to 30?km from the lakes. Selected variables highlighted the importance of burned area and fire severity in explaining lacustrine charcoal. The charcoal influx was thus driven by fire area and severity during the production process. The dispersion process of particles resulted mostly of wind transportation within the regional (<30?km) source area. Overall, charcoal median surface area represents a reliable proxy for reconstructing past burned areas and fire severities.
Chéïma Barhoumi , Odile Peyron , Sébastien Joannin, Dmitri Subetto, Alexander Kryshen, Igor Drobyshev, Martin-Philippe Girardin, Benoit Brossier, Laure Paradis, Thierry Pastor, Samuel Alleaume, Adam A. Ali. Gradually increasing forest fire activity during the Holocene in the northern Ural region (Komi Republic, Russia) 2019. Holocene 1906
DOI : 10.1177/0959683619865593
In many boreal regions of Russia the past natural variability of forest fire activity remains largely undocumented, preventing accurate assessment of the impact of current climate warming on forest ecosystem dynamics. This study aims to reconstruct the Holocene fire history of the northern Ural mountain foothills, in the Komi Republic, based on analyses of charcoal particles from peatland deposits and coupled with dendrochronological investigations. The results show that there was a gradual increase in forest fire activity during the past 11,000 years. Between 11,000 and 5100 cal. yr BP, the mean fire return interval (FRI) oscillated between 600 and 200 years. During this period, regional data showed that cold temperature, humid climatic conditions, combined with steppe vegetation between 11,000?9000 cal. BP, and then the development of spruce-dominated forest between 9300 and 4600 cal. yr BP, were less conducive to fires. After 5100 cal. yr BP, a gradual increase in drought conditions through reduced precipitations, associated with the establishment of a Scots pine forest favored fire frequency, with a mean FRI under 200 years (range, 200?40 years). Nowadays (since CE 1500), human activity induces an unprecedented fire activity with a mean FRI below 100 years (range, 100?40 years).
Martin-Philippe Girardin, Jeanne Portier, Cécile C. Remy, Adam A. Ali, Jordan Paillard, Olivier Blarquez, Hugo Asselin, Sylvie Gauthier, Yves Bergeron, Pierre Grondin. Coherent signature of warming-induced extreme sub-continental boreal wildfire activity 4,800 and 1,100 years BP. 2019. Environmental Research Letters 14(12):124042
DOI : 10.1088/1748-9326/ab59c9
Climate changes are expected to progressively increase extreme wildfire frequency in forests. Finding past analogs for periods of extreme biomass burning would provide valuable insights regarding what the effects of warming might be for tree species distribution, ecosystem integrity, atmospheric greenhouse gas balance, and human safety. Here, we used a network of 42 lake-sediment charcoal records across a ~2000 km transect in eastern boreal North America to infer widespread periods of wildfire activity in association with past climate conditions. The reconstructed fluctuations in biomass burning are broadly consistent with variations in ethane concentration in Greenland polar ice cores. Biomass burning fluctuations also significantly co-varied with Greenland temperatures estimated from ice cores, at least for the past 6000 years. Our retrospective analysis of past fire activity allowed us to identify two fire periods centered around 4800 and 1100 BP, coinciding with large-scale warming in northern latitudes and having respectively affected an estimated ~71% and ~57% of the study area. These two periods co-occurred with widespread decreases in mean fire-return intervals. The two periods are likely the best analogs for what could be anticipated in terms of impacts of fire on ecosystem services provided by these forests in coming decades.
Yves Bergeron, Dominic Senici, Cécile C. Remy, Laure Paradis, Han Chen, Martin Lavoie, Adam A. Ali. Coniferization of the mixed?wood boreal forests under warm climate. 2019. Journal of Quaternary Science 34(7):509-518
DOI : 10.1002/jqs.3136
Mixed?wood boreal forests are characterized by a heterogeneous landscape dominated by coniferous or deciduous species depending on stand moisture and fire activity. Our study highlights the long?term drivers of these differences between landscapes across mixed?wood boreal forests to improve simulated vegetation dynamics under predicted climate changes. We investigate the effects of main climate trends and wildfire activities on the vegetation dynamics of two areas characterized by different stand moisture regimes during the last 9000 years. We performed paleofire and pollen analyses in the mixed?wood boreal forest of north?western Ontario, derived from lacustrine sediment deposits, to reconstruct historical vegetation dynamics, which encompassed both the Holocene climatic optimum (ca. 8000–4000 a bp) and the Neoglacial period (ca. 4000 a bp). The past warm and dry period (Holocene climatic optimum) promoted higher fire activity that resulted in an increase in coniferous species abundance in the xeric area. The predicted warmer climate and an increase in drought events should lead to a coniferization of the xeric areas affected by high fire activity while the mesic areas may retain a higher broadleaf abundance, as these areas are not prone to an increase in fire activity.
Carole Bastianelli, Yves Bergeron, Adam A. Ali, Christelle Hely-Alleaume, David Paré. Tracking Open Versus Closed-Canopy Boreal Forest Using
the Geochemistry of Lake Sediment Deposits. 2019. JGR Biogeosciences 124(5):1278-1289
DOI : 10.1029/2018JG004647
Identifying geochemical paleo?proxies of vegetation type in watersheds could become a powerful tool for paleoecological studies of ecosystem dynamics, particularly when commonly used proxies, such as pollen grains, are not suitable. In order to identify new paleological proxies to distinguish ecosystem types in lake records, we investigated the differences in the sediment geochemistry of lakes surrounded by two boreal forest ecosystems dominated by the same tree species: closed?canopy black spruce?moss forests (MF) and open?canopy black spruce?lichen woodlands (LW). This study was designed as a first calibration step between terrestrial modern soils and lacustrine sediments (0–1000 cal yr BP) on six lake watersheds. In a previous study, differences in the physical and geochemical properties of forest soils had been observed between these two modern ecosystems. Here we show that the geochemical properties of the sediments varied between the six lakes studied. While we did not identify geochemical indicators that could solely distinguish both ecosystem types in modern sediments, we observed intriguing differences in concentrations of C:N ratio, carbon isotopic ratio, and aluminum oxide species, and in the stabilization of their geochemical properties with depth. The C accumulation rates at millennial scale were significantly higher in MF watersheds than in LW watersheds. We suggest that these variations could result from organic matter inflows that fluctuate depending on forest density and ground vegetation cover. Further investigations on these highlighted geochemistry markers need to be performed to confirm whether they can be used to detect shifts in vegetation conditions that have occurred in the past.
Lisa Bajolle, Yves Bergeron, Isabelle Larocque, Emmanuel Gandouin, Martin Lavoie, Adam A. Ali. A chironomid-inferred Holocene temperature record
from a shallow Canadian boreal lake: potentials and pitfalls. 2019. J Paleolimnol 61(1):69-84
DOI : 10.1007/s10933-018-0045-9
The biodiversity of shallow (zmax?5–7 m) lakes is sensitive to water-level and climate changes, but few such aquatic ecosystems have been studied in the context of quantitative climate reconstruction. Lac Lili (unofficial name) is located in the boreal forest of western Quebec, Canada, and was chosen for its shallowness (zmax?=?1.40 m) to assess if chironomid assemblages in the sediments could be used to reconstruct Holocene temperature fluctuations quantitatively. Inferred temperatures displayed a decreasing trend from a maximum value ca. 8000–3500 cal year BP, slight warming between ca. 3500 and 3000 cal year BP, followed by cooling to the present. Although chironomid assemblages were influenced by factors other than climate, primarily water depth and changes in macrophyte richness, the reconstructed Holocene temperature pattern was very similar to the known regional climate history. Temperature inferences derived from the chironomid assemblages were, however, warmer than the two reference periods. This deviation was likely a consequence of three factors: (1) shallowness of the lake, which favoured littoral taxa with warmer-than-today temperature optima, (2) the low number of lakes warmer than 16 °C in the training set, and (3) the absence of shallow lakes in the training set.
Lionel Navarro, Anne-Élizabeth Harvey, Yves Bergeron, Hubert Morin, Adam A. Ali. A Holocene landscape dynamic multiproxy reconstruction: How do interactions between fire and insect outbreaks shape an ecosystem over long time scales? 2018. PlosOne 13(10):e0204316
DOI : 10.1371/journal.pone.0204316
At a multi-millennial scale, various disturbances shape boreal forest stand mosaics and the distribution of species. Despite the importance of such disturbances, there is a lack of studies focused on the long-term dynamics of spruce budworm (Choristoneura fumiferana (Clem.)) (SBW) outbreaks and the interaction of insect outbreaks and fire. Here, we combine macrocharcoal and plant macrofossils with a new proxy-lepidopteran scalesto describe the Holocene ecology around a boreal lake. Lepidopteran scales turned out to be a more robust proxy of insect outbreaks than the traditional proxies such as cephalic head capsules and feces. We identified 87 significant peaks in scale abundance over the last 10 000 years. These results indicate that SBW outbreaks were more frequent over the Holocene than suggested by previous studies. Charcoal accumulation rates match the established fire history in eastern Canada: A more fire-prone early and late Holocene and reduced fire frequency during the mid-Holocene. Although on occasion, both fire and insect outbreaks were coeval, our results show a generally inverse relationship between fire frequency and insect outbreaks over the Holocene. © 2018 Navarro et al.This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Andy Hennebelle, Julie C. Aleman, Yves Bergeron, Daniel Borcard, Pierre Grondin, Olivier Blarquez, Adam A. Ali. Using paleoecology to improve reference conditions for ecosystem-based
management in western spruce-moss subdomain of Québec. 2018. For. Ecol. Manage. 430:157-165
DOI : 10.1016/j.foreco.2018.08.007
Ecosystem based management in Québec is framed by reference conditions defining percentage of old-growth forest (>100-years-old) and forest composition characterizing pre-industrial forest landscapes. In the western spruce-moss bioclimatic subdomain (154?184?km2) a fire cycle estimated at 150?years was used to target that 49% of the landscape has to be composed of old-growth forest. Yet, this target was developed using past (19th–20th C.) climate and vegetation data and assume that environment and ecosystem processes are homogeneous for the entire western spruce-moss bioclimatic subdomain. The wide spatial and narrow temporal windows limit the application of reference conditions under ongoing climate change.
Our aim was to classify current vegetation heterogeneity of the western spruce-moss subdomain into homogeneous zones and to study the long-term history of fire and vegetation within these zones. This approach will help to refine forest management targets that are based upon short-term records by providing a long-term perspective that is needed for the forests to be managed within their natural range of variability. Modern forest inventories data were used along with climate, physical variables, and natural and human disturbances to study the current vegetation-environment interactions among the western spruce-moss subdomain. We also used 18 published sedimentary pollen and charcoal series to reconstruct Holocene vegetation and Fire Return Intervals (FRI).
Contemporary data revealed 4 zones with homogeneous interactions between vegetation and environment. Pollen analysis revealed three long-term vegetation paths: early successional species dominance, late to early species transition and late successional species dominance. These suggest that modern forest composition results from Holocene trajectories occurring within each zone. Holocene mean FRI (mFRI) ranged from 222 to 258 years across the subdomain, resulting in old-growth forests ranging between 64% and 68%, depending upon the zone.
Paleoecological and contemporary results support that to make forest management more sustainable, current landscape heterogeneity that arises from millennial forest composition trajectories and fire cycle dynamics should be taken into account by down-scaling the previously established reference conditions.
Abed Nego Jules, Yves Bergeron, Hugo Asselin, Adam A. Ali. Are marginal balsam fir and eastern
white cedar stands relics from once
more extensive populations in
north-eastern North America? 2018. Holocene 28(10):1672-1679
DOI : 10.1177/0959683618782601
Marginal stands of balsam fir (Abies balsamea [L.] Mill.) and eastern white cedar (Thuja occidentalis L.) are found north of their limits of continuous distribution in eastern North America. Regional-scale paleoecological studies have suggested that fir and cedar populations could have had larger extents in the past. This study aimed at verifying this hypothesis at the local scale. Wood charcoal fragments were collected from the soils of two marginal fir and cedar stands as well as from 15 sites in the surrounding forest matrix where the species are absent currently. Anatomical identification and radiocarbon-dating showed that fir was more extensive in the study area until about 680 cal. BP, representing up to 31% of the charcoal assemblages at sites where it is currently absent. The evidence is less conclusive for cedar, however, although some of the charcoal fragments from the matrix sites could have been either fir or cedar (undistinguishable). Most of the dated fir/cedar charcoal in the matrix were from the ‘Medieval Warm Period’ (ca. 1000 cal. BP), suggesting contraction may have occurred at that time. Marginal fir – and possibly cedar – stands are thus relics of once more extensive populations. Fire is likely the main factor having contributed to the contraction of the species’ distributions. Fir and cedar are now relegated to areas where fires are less frequent and severe, such as the shores of lakes and rivers.
Cécile Fouquemberg, Cécile C. Remy, Benjamin Andrieux, Gabriel Magnan, Benoit Brossier, Yves Bergeron, Hugo Asselin, Brigitte Talon, Lisa Bajolle, Adam A. Ali, Olivier Blarquez, Pierre Grondin. Guidelines for the use and interpretation of paleofire reconstructions based on various archives and proxies. 2018. Quaternary Research 193:312-322
DOI : 10.1016/j.quascirev.2018.06.010
We present a comparative analysis of fire reconstructions from tree rings and from wood charcoal preserved in forest soils, peat and lake sediments. Our objective is to highlight the benefits and limits of different archives and proxies to reconstruct fire histories. We propose guidelines to optimize proxy and archive choice in terms of spatial and temporal scales of interest. Comparisons were performed for two sites in the boreal forest of northeastern North America. Compared to others archives, tree-ring analysis remains the best choice to reconstruct recent fires (<1000 years). For longer periods (from several centuries to millennia), lake charcoal can be used to reconstruct regional or local fire histories depending on the method used, but the focus should be on historical trends rather than on the identification of individual fire events. Charcoal preserved in peat and soils can be used to identify individual fire, but sometimes cover shorter time periods than lake archives.
Justin Waito, Yves Bergeron, France Conciatori, Adam A. Ali, Martin-Philippe Girardin, Jacques Tardif. Recent fire activity in the boreal eastern interior of North America
is below that of the past 2000 yr. 2018. Ecosphere 9(6):e02287
DOI : 10.1002/ecs2.2287
The North American boreal forest has been developing since the end of the last glaciation
approximately 10,000 yr ago. With climate warming and human occupation, it is anticipated that fire danger,
ignition, and activity will be increasing, compromising forests’ benefits for generations to come. In this
study, we show, however, that a century of rapid climate changes and human densification has had the
opposite effect in the boreal eastern interior of the North American continent, reducing biomass burning to
values below two millennia of historical levels. A multi-millennial fire history was reconstructed for eight
forested landscapes from the Lake of the Woods Ecoregion (LWE) located at the boreal–prairie ecotone.
Fire history was reconstructed using a combination of archival (period 1920–2010), tree-ring (stand initiations
and fire scars: period 1690–2010), and lake sediment charcoal (2500 BP to present) records. The archival
record revealed recent large fires (>200 ha) in 1948, 1980, and 1988. An additional 19 fires were
identified by the fire-scar record. Fire events in 1805, 1840, 1863, and the 1890s were identified in numerous
locations around multiple lakes suggesting that they were of large extents. In accordance with the tree-ring
record, the charcoal accumulation rate (CHAR) peak record generally identified the major fires but tended
to lag from the tree-ring records by several decades. Within LWE, the long-term charcoal record revealed
that CHAR was higher for each lake in the earlier portion of the record including the warm Medieval
Climate Anomaly (AD 900 to AD 1000), followed by a progressive decrease toward the cool Little Ice
Age period. This decline was abruptly interrupted in the mid- to late 19th century with large synchronized
fires, also reported over western and central North America, and resumed approximately four decades
later. Fire disturbance level is today below the historical range, despite the accentuated climate warming.
Aging of the forest landscape may create biodiversity loss notably in fire-adapted species while at the same
time setting the tone for major fires in upcoming decades if no action is taken for managing fuels.
Lisa Bajolle, Isabelle Larocque, Emmanuel Gandouin, Yves Bergeron, Adam A. Ali, Martin Lavoie. Major postglacial summer temperature changes in the central
coniferous boreal forest of Quebec (Canada) inferred using
chironomid assemblages. 2018. Journal of Quaternary Science 33(4):409-420
DOI : 10.1002/jqs.3022
Chironomid head capsules preserved in lake sediments were used to reconstruct 8200 years of summer temperatures in the boreal forest of north?eastern Canada. Two training sets were used derived from Canadian and Eastern Canadian transfer functions. Both models reconstructed similar climate patterns, but the Canadian model provided temperatures generally 2–3?°C lower than the Eastern Canadian model. Three main thermal changes inferred by chironomids were: (i) the Holocene Thermal Maximum, which occurred between 8 and 5k cal a BP, with temperatures generally higher than today's, maximum temperatures between 8 and 6.5k cal a BP, and an average of?+?0.9?°C; (ii) the Medieval Climate Anomaly around 1.1–1.2k cal a BP with an amplitude of?+?0.7?°C; and (iii) a colder period reconstructed between the 14th and 19th centuries, corresponding to the Little Ice Age, with summer temperatures on average ?0.5?°C lower than the climate normal. For each of these three climatic events, the timing and the amplitude of changes were similar with other published regional, North American and Northern Hemisphere records.
Cécile C. Remy, Gabriel Magnan, Yves Bergeron, Olivier Blarquez, Martin Lavoie, Adam A. Ali, Christelle Hely-Alleaume. Different regional climatic drivers of Holocene large wildfires in boreal forests of northeastern America. 2017. Environmental Research Letters 12(3):article 035005
Global warming could increase climatic instability and large wildfire activity in circumboreal regions, potentially impairing both ecosystem functioning and human health. However, links between large wildfire events and climatic and/or meteorological conditions are still poorly understood, partly because few studies have covered a wide range of past climate-fire interactions. We compared palaeofire and simulated climatic data over the last 7000 years to assess causes of large wildfire events in three coniferous boreal forest regions in north-eastern Canada. These regions span an east-west cline, from a hilly region influenced by the Atlantic Ocean currently dominated by Picea mariana and Abies balsamea to a flatter continental region dominated by Picea mariana and Pinus banksiana. The largest wildfires occurred across the entire study zone between 3000 and 1000 cal. BP. In western and central continental regions these events were triggered by increases in both the fire-season length and summer/spring temperatures, while in the eastern region close to the ocean they were likely responses to hydrological (precipitation/evapotranspiration) variability. The impact of climatic drivers on fire size varied spatially across the study zone, confirming that regional climate dynamics could modulate effects of global climate change on wildfire regimes.
Carole Bastianelli, Julien Beguin, Yves Bergeron, Adam A. Ali, Christelle Hely-Alleaume, David Paré, Pierre Grondin. Boreal coniferous forest density leads to significant variations in soil physical and geochemical properties. 2017. Biogeosciences 14:3445-3459
DOI : 10.5194/bg-14-3445-2017
At the northernmost extent of the managed forest in Quebec, Canada, the boreal forest is currently undergoing an ecological transition between two forest ecosystems. Open lichen woodlands (LW) are spreading southward at the expense of more productive closed-canopy black spruce–moss forests (MF). The objective of this study was to investigate whether soil properties could distinguish MF from LW in the transition zone where both ecosystem types coexist. This study brings out clear evidence that differences in vegetation cover can lead to significant variations in soil physical and geochemical properties.
Here, we showed that soil carbon, exchangeable cations, and iron and aluminium crystallinity vary between boreal closed-canopy forests and open lichen woodlands, likely attributed to variations in soil microclimatic conditions. All the soils studied were typical podzolic soil profiles evolved from glacial till deposits that shared a similar texture of the C layer. However, soil humus and the B layer varied in thickness and chemistry between the two forest ecosystems at the pedon scale. Multivariate analyses of variance were used to evaluate how soil properties could help distinguish the two types at the site scale. MF humus (FH horizons horizons composing the O layer) showed significantly higher concentrations of organic carbon and nitrogen and of the main exchangeable base cations (Ca, Mg) than LW soils. The B horizon of LW sites held higher concentrations of total Al and Fe oxides and particularly greater concentrations of inorganic amorphous Fe oxides than MF mineral soils, while showing a thinner B layer. Overall, our results show that MF store three times more organic carbon in their soils (B+FH horizons, roots apart) than LW. We suggest that variations in soil properties between MF and LW are linked to a cascade of events involving the impacts of natural disturbances such as wildfires on forest regeneration that determines the vegetation structure (stand density) and composition (ground cover type) and their subsequent consequences on soil environmental parameters (moisture, radiation rate, redox conditions, etc.). Our data underline significant differences in soil biogeochemistry under different forest ecosystems and reveal the importance of interactions in the soil–vegetation–climate system for the determination of soil composition.
Cécile C. Remy, Yves Bergeron, Hugo Asselin, Martin Lavoie, France Oris, Adam A. Ali, Christelle Hely-Alleaume, Martin-Philippe Girardin, Pierre Grondin. Wildfire size alters long-term vegetation trajectories in boreal forests of eastern North America. 2016. J. of Biogeography 43(12):vv
DOI : 10.1111/jbi.12921
Laure Paradis, Yves Bergeron, Samira Ouarmim, Hugo Asselin, Christelle Hely-Alleaume, Adam A. Ali. Burning Potential of Fire Refuges in the Boreal
Mixedwood Forest. 2016. Forests 7(10):246
DOI : 10.3390/f7100246
In boreal ecosystems, wildfire severity (i.e., the extent of fire-related tree mortality) is affected by environmental conditions and fire intensity. A burned area usually includes tree patches that partially or entirely escaped fire. There are two types of post-fire residual patches: (1) patches that only escaped the last fire; and (2) patches with lower fire susceptibility, also called fire refuges, that escaped several consecutive fires, likely due to particular site characteristics. The main objective of this study was to test if particular environmental conditions and stand characteristics could explain the presence of fire refuges in the mixedwood boreal forest. The FlamMap3 fire behavior model running at the landscape scale was used on the present-day Lake Duparquet forest mosaic and on four other experimental scenarios. FlamMap3 was first calibrated using BehavePlus and realistic rates of fire spread obtained from the Canadian Fire Behavior Prediction system. The results, based on thousands of runs, exclude the effects of firebreaks, topography, fuel type, and microtopography to explain the presence of fire refuges, but rather highlight the important role of moisture conditions in the fuel beds. Moist conditions are likely attributed to former small depressions having been filled with organic matter rather than present-day variations in ground surface topography.
Yves Bergeron, Anne de Vernal, Anders Moberg, Mats Niklasson, Igor Drobyshev, Adam A. Ali. Atlantic SSTs control regime shifts
in forest fire activity of Northern
Scandinavia. 2016. Nature Scientific Reports 6, Article number: 22532
DOI : 10.1038/srep22532
Understanding the drivers of the boreal forest fire activity is challenging due to the complexity of the interactions driving fire regimes. We analyzed drivers of forest fire activity in Northern Scandinavia (above 60 N) by combining modern and proxy data over the Holocene. The results suggest that the cold climate in northern Scandinavia was generally characterized by dry conditions favourable to periods of regionally increased fire activity. We propose that the cold conditions over the northern North Atlantic, associated with low SSTs, expansion of sea ice cover, and the southward shift in the position of the subpolar gyre, redirect southward the precipitation over Scandinavia, associated with the westerlies. This dynamics strengthens high pressure systems over Scandinavia and results in increased regional fire activity. Our study reveals a previously undocumented teleconnection between large scale climate and ocean dynamics over the North Atlantic and regional boreal forest fire activity in Northern Scandinavia. Consistency of the pattern observed annually through millennium scales suggests that a strong link between Atlantic SST and fire activity on multiple temporal scales over the entire Holocene is relevant for understanding future fire activity across the European boreal zone.
Olivier Blarquez, Yves Bergeron, Bianca Fréchette, Adam A. Ali, Pierre Grondin, Christelle Hely-Alleaume, Martin-Philippe Girardin. Regional paleofire regimes
affected by non-uniform climate,
vegetation and human drivers. 2015. Nature 5:13356
DOI : 10.1038/srep13356
Climate, vegetation and humans act on biomass burning at different spatial and temporal scales. In this study, we used a dense network of sedimentary charcoal records from eastern Canada to reconstruct regional biomass burning history over the last 7000 years at the scale of four potential vegetation types: open coniferous forest/tundra, boreal coniferous forest, boreal mixedwood forest and temperate forest. The biomass burning trajectories were compared with regional climate trends reconstructed from general circulation models, tree biomass reconstructed from pollen series, and human population densities. We found that non-uniform climate, vegetation and human drivers acted on regional biomass burning history. In the open coniferous forest/tundra and dense coniferous forest, the regional biomass burning was primarily shaped by gradual establishment of less climate-conducive burning conditions over 5000 years. In the mixed boreal forest an increasing relative proportion of flammable conifers in landscapes since 2000?BP contributed to maintaining biomass burning constant despite climatic conditions less favourable to fires. In the temperate forest, biomass burning was uncoupled with climatic conditions and the main driver was seemingly vegetation until European colonization, i.e. 300?BP. Tree biomass and thus fuel accumulation modulated fire activity, an indication that biomass burning is fuel-dependent and notably upon long-term co-dominance shifts between conifers and broadleaf trees.
Yves Bergeron, Dominic Senici, Han Chen, Adam A. Ali. The effects of forest fuel connectivity on
spatiotemporal dynamics of Holocene fire regimes in
the central boreal forest of North America. 2015. Journal of Quaternary Science 30(4):365-375
DOI : 10.1002/jqs.2790
Understanding fire regime dynamics is central to predicting forest structure and the compositional dynamics of boreal forests. Spatial and temporal variations in fire frequency in central Canadian boreal forests over the last 10 000 years were examined to evaluate the influence of bottom-up controls on the regional fire regime. We analysed macroscopic charcoal larger than 160??m from sediment cores from six lakes to reconstruct fire history and performed GIS analysis of regional landscape features to investigate how fire frequency has changed temporally and how non-climatic factors may have affected long-term fire frequency. Our generalized linear mixed model revealed that temporal changes in fire return intervals (FRIs) were highly dependent on landscape connectivity as inferred through the abundance of natural firebreaks in the form of open water lakes and wetlands. FRIs did not change significantly among highly connected landscapes throughout the Holocene; in contrast, FRIs were significantly longer among poorly connected landscapes in the early Holocene (10–5 cal ka BP), suggesting that the abundant regional firebreaks limited fire spread. All sites had similar FRIs in the late Holocene. The diminishing influence of firebreaks suggests that the regional climate during the late Holocene has overshadowed the influences of the bottom-up controls on fire activities.
Ahmed El Guellab, Yves Bergeron, Sylvie Gauthier, Adam A. Ali, Hugo Asselin. Holocene variations of wildfire occurrence as a
guide for sustainable management of the
northeastern Canadian boreal forest. 2015. Forest Ecosystems 2:15
DOI : 10.1186/s40663-015-0039-2
Background
Cumulative impacts of wildfires and forest harvesting can cause shifts from closed-crown forest to open woodland in boreal ecosystems. To lower the probability of occurrence of such catastrophic regime shifts, forest logging must decrease when fire frequency increases, so that the combined disturbance rate does not exceed the Holocene maximum. Knowing how climate warming will affect fire regimes is thus crucial to sustainably manage the forest. This study aimed to provide a guide to determine sustainable forest harvesting levels, by reconstructing the Holocene fire history at the northern limit of commercial forestry in Quebec using charcoal particles preserved in lake sediments.
Methods
Sediment cores were sampled from four lakes located close to the northern limit of commercial forestry in Quebec. The cores were sliced into consecutive 0.5 cm thick subsamples from which 1 cm3 was extracted to count and measure charcoal particles larger than 150 microns. Age-depth models were obtained for each core based on accelerator mass spectroscopy (AMS) radiocarbon dates. Holocene fire histories were reconstructed by combining charcoal counts and age-depth models to obtain charcoal accumulation rates and, after statistical treatment, long-term trends in fire occurrence (expressed as number of fires per 1000 years).
Results
Fire occurrence varied between the four studied sites, but fires generally occurred more often during warm and dry periods of the Holocene, especially during the Holocene Thermal Maximum (7000–3500 cal. BP), when fire occurrence was twice as high as at present.
Conclusions
The current fire regime in the study area is still within the natural range of variability observed over the Holocene. However, climatic conditions comparable to the Holocene Thermal Maximum could be reached within the next few decades, thus substantially reducing the amount of wood available to the forest industry.
Yves Bergeron, Samira Ouarmim, Christelle Hely-Alleaume, Adam A. Ali, Hugo Asselin. Evaluating the persistence of post-fire residual patches in the eastern Canadian boreal mixedwood forest. 2015. Boreas 44(1):230-239
DOI : 10.1111/bor.12087
Wildfires in boreal forest ecosystems usually spare tree stands called post-fire residual patches. There are two types of post-fire residual patches: (1) patches that only escaped fire by chance, probably due to local meteorological conditions unsuitable for fire spread at the moment fire reached their surroundings (random post-fire residual patches), and (2) patches with lower fire susceptibility, that escaped several consecutive fires, likely due to particular site characteristics (fire refuges). Special conservation efforts could target fire refuges owing to their old age, long ecological continuity, and potential specific biological diversity. Here we compared the stand characteristics of 13 post-fire residual patches from the eastern Canadian boreal mixedwood forest to develop guidelines and information for forest managers to differentiate fire refuges from random post-fire residual patches. Two main structural characteristics differentiated fire refuges from random post-fire residual patches: mean tree diameter and thickness of the soil organic matter layer. Thick organic matter accumulation in fire refuges is likely linked to a paludification process, which in turn reduces stand productivity, and thus, mean tree diameter.
Yves Bergeron, France Oris, Laure Paradis, Walter Finsinger, Adam A. Ali, Hugo Asselin. Charcoal dispersion and deposition in boreal lakes
from 3 years of monitoring: Differences
between local and regional fires. 2014. Geophysical Research Letters 41:6743-6752
DOI : 10.1002/2014GL060984
To evaluate the influence of long-distance transport of charcoal particles on the detection of local wildfires from lake sediment sequences, we tracked three consecutive years of charcoal deposition into traps set within seven boreal lakes in northeastern Canada. Peaks in macroscopic charcoal accumulation (>150?µm) were linked to both local (inside the watershed) and regional wildfires. However, regional fires were characterized by higher proportions of small particles (<0.1?mm2) in charcoal assemblages. We conclude that the analysis of particle size distribution is useful to discriminate “true” local fires from regional wildfires.
France Oris, Yves Bergeron, Walter Finsinger, Hugo Asselin, Adam A. Ali. Effect of increased fire activity on global warming in the boreal forest. 2014. Environ. Rev.
DOI : 10.1139/er-2013-0062
Les feux de forêt constituent une importante perturbation en forêt boréale. Le climat, la température, la topographie, la végétation, les dépôts de surface et les activités humaines représentent autant de facteurs pouvant les influencer. À l’inverse, les feux de forêt affectent le climat par l’émission de gaz et d’aérosols et modifient l’albédo de surface, les processus édaphiques et la dynamique de la végétation. On ne connaît pas encore très bien l’effet net de ces facteurs, mais ils semblent avoir exercé une rétroaction négative sur le climat au cours du XXe siècle. Cependant, on prédit une augmentation des feux de forêt vers la fin du XXIe siècle susceptible de modifier leurs effets sur le climat vers une rétroaction positive capable d’exacerber réchauffement planétaire. Cette synthèse présente (1) une revue d’ensemble des régimes des feux et de la succession de la végétation en forêts boréales, (2) les effets sur le climat des émissions de combustion et des changements du fonctionnement des écosystèmes après feu, (3) les effets des variations du régime de feu sur le climat, particulièrement sur les changements de stock de carbone et d’albédo de surface, (4) une approche intégrée des effets des feux sur la dynamique du climat et (5) l’implication de l’augmentation de l’activité des feux sur le réchauffement planétaire en calculant le forçage radiatif de plusieurs facteurs vers 2100 en région boréale, avant de discuter les résultats et d’exposer les limites des données. Généralement, les pertes en carbone occasionnées par les feux de forêt en région boréale augmenteront dans le futur et leur effet sur les stocks de carbone (0,37 W/m2/décennie) sera plus grand que l’effet du feu sur l’albédo de surface (−0,09 W/m2/décennie). L’effet net des émissions d’aérosols venant des feux en forêt boréale causera vraisemblablement une rétroaction positive sur le réchauffement planétaire. Cette synthèse met l’accent sur l’importance des rétroactions entre les feux et le climat en forêt boréale. Elle présente les limites et les incertitudes à aborder dans les prochaines études, surtout en relation avec les effets de la fertilisation par le CO2 sur la productivité forestière, laquelle pourrait contrebalancer ou atténuer les effets du feu.
Yves Bergeron, Samira Ouarmim, Hugo Asselin, Christelle Hely-Alleaume, Adam A. Ali. Stand structure in fire refuges of the eastern Canadian boreal mixedwood forest. 2014. For. Ecol. Manage. 324:1-7
DOI : 10.1016/j.foreco.2014.03.034
Wildfires in boreal forest ecosystems usually spare tree stands called post-fire residual patches. There are two types of post-fire residual patches: (1) patches that only escaped fire by chance, probably due to local meteorological conditions unsuitable for fire spread at the moment fire reached their surroundings (random post-fire residual patches), and (2) patches with lower fire susceptibility, that escaped several consecutive fires, likely due to particular site characteristics (fire refuges). Special conservation efforts could target fire refuges owing to their old age, long ecological continuity, and potential specific biological diversity. Here we compared the stand characteristics of 13 post-fire residual patches from the eastern Canadian boreal mixedwood forest to develop guidelines and information for forest managers to differentiate fire refuges from random post-fire residual patches. Two main structural characteristics differentiated fire refuges from random post-fire residual patches: mean tree diameter and thickness of the soil organic matter layer. Thick organic matter accumulation in fire refuges is likely linked to a paludification process, which in turn reduces stand productivity, and thus, mean tree diameter.
France Oris, Walter Finsinger, Marie-Eve Ferland, Yves Bergeron, Olivier Blarquez, Hugo Asselin, Christelle Hely-Alleaume, Adam A. Ali. Long-term fire history in northern quebec: Implications for the northern limit of commercial forests. 2014. Journal of Applied Ecology 51(3):675-683
DOI : 10.1111/1365-2664.12240
Fire frequency is expected to increase in boreal forests over the next century owing to climate change. In Quebec (Canada), the location of the northern limit of commercial forests (c. 51 °N) was established in 2000 taking into account mainly forest productivity and fire risk. The location of the limit is currently under debate and is being re-evaluated based on a more extensive survey of the territory. We characterized the natural variability of fire occurrence (FO) in the area surrounding the northern limit, and these results are a useful contribution to discussions on the re-evaluation of its location. Regional FO over the last 7000 years was reconstructed from sedimentary charcoal records from 11 lakes located in three regions surrounding the northern limit (i.e. south, north and near the limit). Holocene simulated precipitation and temperature from a general circulation model (GCM) were used to identify the long-term interactions between climate and fire. Fire histories displayed similar trends in all three regions, with FO increasing from 7000 calibrated years before present (cal. years BP) to reach a maximum at 4000-3000 cal. years BP, before decreasing during the late-Holocene. This trend matches the simulated changes in climate, characterized by drier and warmer conditions between 7000 and 3500 cal. years BP and cooler and moister conditions between 3500 and 0 cal. years BP. Northern ecosystems displayed higher sensitivity to climate change. The natural variability of FO was narrower in the southern region compared with the limit and northern regions. An abrupt decrease in FO was recorded close to and north of the limit at 3000 cal. years BP, whereas the decrease was more gradual in the south. Synthesis and applications. We reconstructed the natural variability in fire activity over the last 7000 years near the current location of the northern limit of commercial forests in Quebec. Fire occurrences were more sensitive to climate change near to and north of the limit of commercial forestry. In the context of predicted increase in fire activity, the lower resilience of northern forests advocates against a northern repositioning of the limit of commercial forests. © 2014 The Authors.
Benoit Brossier, France Oris, Walter Finsinger, Hugo Asselin, Yves Bergeron, Adam A. Ali. Using tree-ring records to calibrate peak detection in fire reconstructions based on sedimentary charcoal records. 2014. Holocene 24(6):635-645
DOI : 10.1177/0959683614526902
We compared fire episodes over the past 150 years reconstructed using charcoal particles retrieved from well-dated sediment deposits from two small lakes in the eastern Canadian boreal forest, with dendrochronological reconstructions of fire events from the corresponding watersheds. Fire scars and age structure of living trees highlighted three fire events (AD 1890, 1941, and 1989). To explore the ability to detect these fire events based on sedimentary charcoal records, we explored the influence of two user-determined parameters of a widely used peak-detection algorithm (the CharAnalysis software): (1) the temporal resolution used to interpolate charcoal series and (2) the width of the smoothing window used to model background noise. The signal-to-noise index (SNI) is often used to evaluate the ability to detect peaks in sedimentary charcoal records, which can be related to fire events. SNI values >3 identify records appropriate for peak detection. Selecting standard settings in paleoecological studies (median temporal resolution of the entire sequence and 500- to 1000-year window width) yielded higher global SNI values but failed to detect most recent fire events. Instead, selecting a shorter reference period (the past ~150 years) to determine the temporal resolution to interpolate the charcoal series and a narrower smoothing window (100 years) best matched the tree-ring data despite lower SNI values (often <3.0). However, Holocene fire history differed markedly when reconstructed using different smoothing window widths (100–150 years vs >300 years). Consequently, we suggest using the smallest window width yielding a SNI >3. Practitioners must not necessarily focus on obtaining the highest possible SNI, usually related to wide smoothing windows. We also suggest that fire history reconstructions should focus on core sections presenting fairly constant sedimentation rates. Alternatively, sediments could be subsampled after age–depth models have been obtained.
Samira Ouarmim, Yves Bergeron, Hugo Asselin, Adam A. Ali, Christelle Hely-Alleaume. Long-term dynamics of fire refuges in boreal mixedwood forests. 2014. Journal of Quaternary Science 29(2):123-129
DOI : 10.1002/jqs.2685
Burned areas in boreal mixedwood forests usually include tree patches that partially or entirely escaped fire. Some of these post-fire residual stands – called fire refuges – can escape several consecutive fires due to particular microsite conditions. Despite their potential importance as biodiversity hotspots, the long-term forest dynamics of fire refuges is unknown. High-resolution analysis of plant macroremains retrieved from forest organic matter profiles sampled in five fire refuges allowed us to describe up to 8000 years of forest dynamics. Our results display the importance of local conditions in forest dynamics. Wildfire was probably prevented by high moisture, as indicated by the presence of aquatic taxa and moisture-tolerant tree species. Lack of stand-replacing fire, coupled with organic matter accumulation, favored the millennial persistence of late-successional tree species. Shifts from spruce/larch dominance to fir/cedar dominance were noted at different occasions during the Holocene, probably resulting from endogenous processes.
Olivier Blarquez, Martin-Philippe Girardin, Bérangère Leys, Adam A. Ali, Julie C. Aleman, Yves Bergeron, Christopher Carcaillet. Paleofire reconstruction based on an ensemble-member strategy
applied to sedimentary charcoal. 2013. Geophysical Research Letters 40(11):2667-2672
DOI : 10.1002/grl.50504
Paleofire events obtained from the statistical treatment of sedimentary charcoal records rely on a number of assumptions and user's choices, increasing the uncertainty of reconstructio\ns. Among the assumptions made when analyzing charcoal series is the choice of a filtering method for raw Charcoal Accumulation Rate (CHARraw). As there is no ultimate CHARraw filtering method, we propose an ensemble-member approach to reconstruct fire events. We modified the commonly used procedure by including a routine replicating the analysis of a charcoal record using custom smoothing parameters. Dates of robust fire events, uncertainties in fire-return intervals and fire frequencies are derived from members' distributions. An application of the method is used to quantify uncertainties due to data treatment in two CHARraw sequences from two different biomes, subalpine and boreal.
Aurélie Genries, Olivier Blarquez, Yves Bergeron, Aurélie Terrier, Adam A. Ali, Martin-Philippe Girardin, Christopher Carcaillet, Christelle Hely-Alleaume. Vegetation limits the impact of a warm climate on boreal wildfires. 2013. New Phytologist
DOI : 10.1111/nph.12322
- Strategic introduction of less flammable broadleaf vegetation into landscapes was suggested as a management strategy for decreasing the risk of boreal wildfires projected under climatic change. However, the realization and strength of this offsetting effect in an actual environment remain to be demonstrated.
- Here we combined paleoecological data, global climate models and wildfire modelling to assess regional fire frequency (RegFF, i.e. the number of fires through time) in boreal forests as it relates to tree species composition and climate over millennial time-scales.
- Lacustrine charcoals from northern landscapes of eastern boreal Canada indicate that RegFF during the mid-Holocene (6000–3000 yr ago) was significantly higher than pre-industrial RegFF (ad c. 1750). In southern landscapes, RegFF was not significantly higher than the pre-industrial RegFF in spite of the declining drought severity. The modelling experiment indicates that the high fire risk brought about by a warmer and drier climate in the south during the mid-Holocene was offset by a higher broadleaf component.
- Our data highlight an important function for broadleaf vegetation in determining boreal RegFF in a warmer climate. We estimate that its feedback may be large enough to offset the projected climate change impacts on drought conditions.
Martin-Philippe Girardin, Adam A. Ali, Christopher Carcaillet, Sylvie Gauthier, Christelle Hely-Alleaume, Héloïse Le Goff, Aurélie Terrier, Yves Bergeron. Fire in managed forests of eastern Canada: Risks and options. 2013. For. Ecol. Manage. 294:238-249
DOI : 10.1016/j.foreco.2012.07.005
In this era of climate change, understanding past and predicting future fire activity are scientific challenges that are central to the development of sustainable forest management practices and policies. Such objectives, however, are difficult to achieve for several reasons. Uncertainties about future fire activity can be superimposed on the short time period covered by existing meteorological data and fire statistics, from which a historical range of variability can be determined. Regional fire activity is also tremendously variable over time, such that contemporary fire records cannot provide information on the full range of fire activity variability a given forest experienced and adapted to. This factor is increasingly important when it comes to determining the resilience of boreal forests to changes in climate and disturbance regimes. In this paper, we present a synthesis of past, present and future trends in seasonal fire danger and fire activity based on data gathered in eastern Canadian boreal forests over the last 20 years, and we provide a critical assessment of the ability to conduct sustainable forest management over the 21st century. The data synthesis provides compelling evidence of a synchronous pattern of decreasing fire-conducive climatic conditions and activity of large fire seasons over the last 2000 years in the eastern coniferous boreal forest. Model simulations suggest that the climate will become drier in upcoming decades, driving future fire activity close to the upper bound of the pre-industrial range of variability. The effects of increasing fire incidence cumulated with forest harvesting may thus pose a risk to forest resilience in the future. This ecological knowledge should help us to define forest management strategies and practices considering future fire activity changes forecasted under climate change. Development of alternative silvicultural interventions that would emulate secondary disturbances (e.g. wind, insects) rather than fire would be necessary to maintain pre-industrial forest characteristics (e.g. composition and age class distribution), and associated forest resilience.
France Oris, Mariusz Lamentowicz, Aurélie Genries, Brice Mourier, Laurent Bremond, Olivier Blarquez, Adam A. Ali, Christopher Carcaillet. Holocene changes in climate and land use drove shifts in the diversity of testate amoebae in a subalpine pond. 2013. Journal of Paleolimnology
DOI : 10.1007/s10933-013-9680-3
Testate amoebae that inhabit peat are sensitive indicators of water table position. In this study, we used testate amoebae in sediments from a mire in the western Alps (Lac du Thyl) to: (1) reconstruct the hydrology of the site over the last 7,000 years, (2) determine how hydrological changes affected testate amoebae diversity and (3) infer past trophic state shifts. The study site is located in one of the driest valleys of the Alps and is thus very sensitive to hydrological changes. Our study revealed that the water table depth increased (dry conditions) between 5,800 and 4,000 cal year BP. This triggered establishment of a Sphagnum-type peat and acidic conditions from 5,700 to 4,000 cal year BP. These processes were independent of ongoing transformations of the terrestrial vegetation and soil in the catchment area. After 1,690 cal year BP, the depth to the water table decreased (wetter conditions) and a minerotrophic fen developed. At the same time, the diversity of testate amoebae increased, probably as a result of deforestation that supported the expansion of grassland. Climate and land use were apparently more important factors controlling the lake hydrology than were changes in vegetation and soil in the catchment. Testate amoebae diversity was linked to land cover. Changes in pH were controlled indirectly by external forcing (climate), but more directly by fluctuations in the level of the water table (internal forcing) and autogenous expansion of Sphagnum.
Dominic Senici, Aurore Lucas, Cungen Chen, Yves Bergeron, Benoit Brossier, Alain Larouche, Olivier Blarquez, Adam A. Ali. Multi-millennial fire frequency and tree abundance differ between xeric and mesic boreal forests in central Canada. 2013. Journal of Ecology
DOI : 10.1111/1365-2745.12047
- Macroscopic sedimentary charcoal and plant macroremains from two lakes, 50 km apart, in north-western Ontario, Canada, were analysed to investigate fire frequency and tree abundance in the central boreal forest. These records were used to examine the controls over the long-term fire regime, and vegetative dynamics associated with fire return intervals (FRIs).
- There were 52 fire events at Lake Ben (surrounded by a xeric landscape) between 10 174 calibrated years before present (cal. year bp) and the present with an average FRI of 186 years with values oscillating between 40 and 820 years. Forty-three fire events were recorded at Lake Small (surrounded by a mesic landscape) between 9972 cal. year bp and the present with an average FRI of 229 years and a range of 60–660 years. FRIs at Lake Small decreased significantly after c. 4500 cal. year bp, whereas at Lake Ben FRIs remained similar throughout the Holocene. Different FRI distributions and independence in the occurrence of fire events were detected between 10 000 and 4500 cal. year bp for the two sites. Between 4500 cal. year bp and the present, similar FRIs were observed, but fires continued to occur independently.
- Longer FRIs resulted in declining abundance of Larix laricina in both landscapes. Longer FRIs resulted in a decline in the abundance of Picea mariana in the xeric landscape, but a marginal increase in the mesic landscape. Abundances of Pinus banksiana, Pinus strobus and Betula papyrifera were unrelated to FRI, underlying that these species maintain their local abundance irrespective of fire frequency.
- Synthesis. Our results show contrasting fire regime dynamics between a xeric and mesic landscape in central boreal forests, Canada. These results highlight the influence of local factors as important drivers of fire frequency at centennial to millennial scales. Local site factors, especially soil moisture, need to be incorporated into predictive models of vegetation response to climate change.
Adam A. Ali, Olivier Blarquez, Fabien Tinquaut, Ahmed El Guellab, Verushka Valsecchi, Laurent Bremond, Aurélie Genries, Sylvie Gauthier, Martin-Philippe Girardin, Aurélie Terrier, Yves Bergeron, Christelle Hely-Alleaume. Control of the multimillennial wildfire size in boreal North America by spring climatic conditions. 2012. PNAS 109(51):20966-20970
DOI : 10.1073/pnas.1203467109
Wildfire activity in North American boreal forests increased during the last decades of the 20th century, partly owing to ongoing human-caused climatic changes. How these changes affect regional fire regimes (annual area burned, seasonality, and number, size, and severity of fires) remains uncertain as data available to explore fire–climate–vegetation interactions have limited temporal depth. Here we present a Holocene reconstruction of fire regime, combining lacustrine charcoal analyses with past drought and fire-season length simulations to elucidate the mechanisms linking long-term fire regime and climatic changes. We decomposed fire regime into fire frequency (FF) and biomass burned (BB) and recombined these into a new index to assess fire size (FS) fluctuations. Results indicated that an earlier termination of the fire season, due to decreasing summer radiative insolation and increasing precipitation over the last 7.0 ky, induced a sharp decrease in FF and BB ca. 3.0 kyBP toward the present. In contrast, a progressive increase of FS was recorded, which is most likely related to a gradual increase in temperatures during the spring fire season. Continuing climatic warming could lead to a change in the fire regime toward larger spring wildfires in eastern boreal North America.
Michelle Garneau, Yves Bergeron, Simon Van bellen, Adam A. Ali. Did fires drive Holocene carbon sequestration in boreal ombrotrophic peatlands of eastern Canada? 2012. Quaternary Research 78(1):50-59
DOI : 10.1016/j.yqres.2012.03.009
Yves Bergeron, Christopher Carcaillet, Pierre J.H. Richard, Bianca Fréchette, Adam A. Ali. Resilience of the boreal forest in response to Holocene fire-frequency changes assessed by pollen diversity and population dynamics. 2010. International Journal of Wildland Fire 19(8):1026-1039
DOI : 10.1071/WF09097
The hypothesis that changes in fire frequency control the long-term dynamics of boreal forests is tested on the basis of paleodata. Sites with different wildfire histories at the regional scale should exhibit different vegetation trajectories. Mean fire intervals and vegetation reconstructions are based respectively on sedimentary charcoal and pollen from two small lakes, one in the Mixedwood boreal forests and the second in the Coniferous boreal forests. The pollen-inferred vegetation exhibits different trajectories of boreal forest dynamics after afforestation, whereas mean fire intervals have no significant or a delayed impact on the pollen data, either in terms of diversity or trajectories. These boreal forests appear resilient to changes in fire regimes, although subtle modifications can be highlighted. Vegetation compositions have converged during the last 1200 years with the decrease in mean fire intervals, owing to an increasing abundance of boreal species at the southern site (Mixedwood), whereas changes are less pronounced at the northern site (Coniferous). Although wildfire is a natural property of boreal ecosystems, this study does not support the hypothesis that changes in mean fire intervals are the key process controlling long-term vegetation transformation. Fluctuations in mean fire intervals alone do not explain the historical and current distribution of vegetation, but they may have accelerated the climatic process of borealisation, likely resulting from orbital forcing.
Laurent Bremond, Charly Favier, Cédric Paitre, Yves Bergeron, Yves Bégin, Adam A. Ali, Christopher Carcaillet, Pierre J.H. Richard. Effects of vegetation zones and climatic changes on fire-induced atmospheric carbon emissions: a model based on paleodata. 2010. International Journal of Wildland Fire 19(8):1015-1025
DOI : 10.1071/WF09096
An original method is proposed for estimating past carbon emissions from fires in order to understand long-term changes in the biomass burning that, together with vegetation cover, act on the global carbon cycle and climate. The past carbon release resulting from paleo-fires during the Holocene is examined using a simple linear model between measured carbon emissions from modern fires and sedimentary charcoal records of biomass burning within boreal and cold temperate forests in eastern Canada (Quebec, Ontario). Direct carbon emissions are estimated for each ecozone for the present period and the fire anomaly per kilo annum (ka) v. present day (0 ka) deduced from charcoal series of 46 lakes and peats. Over the postglacial, the Taiga Shield ecozone does not match the pattern of fire history and carbon release of Boreal Shield, Atlantic Maritime, and Mixedwood Plains ecozones. This feature results from different air mass influences and the timing of vegetation dynamics. Our estimations show, first, that the contribution of the Mixedwood Plains and the Atlantic Maritime ecozones on the total carbon emissions by fires remains negligible compared with the Boreal Shield. Second, the Taiga Shield plays a key role by maintaining important carbon emissions, given it is today a lower contributor.
Adam A. Ali, Martin-Philippe Girardin, Christelle Hely-Alleaume. Wildfires in boreal ecosystems: past, present and some emerging trends. 2010. International Journal of Wildland Fire 19(8):991-995
DOI : 10.1071/WFv19n8_FO
With the emergence of a new forest management paradigm based on the emulation of natural disturbance regimes, interest in fire-related studies has increased in the boreal forest management community. A key issue in this regard is the improvement of our understanding of the variability in past disturbances and its linkages with climate and ecosystems. The surge in research activity has further been exacerbated by the increasing awareness of climate change, which has already exposed boreal forests to greater fire risk in recent decades. It is anticipated that further warming and drying will further enhance fire frequency and area burned in many boreal forests. Better predictions of future fire activity will contribute to better long-term forest planning in managed boreal forests. The 12 papers presented in this special issue exemplify this increased research activity by bringing together studies from diverse disciplines and presenting the latest advances regarding methodological approaches for reconstruction and modelling of past, present and future fire activity. Here we aim to summarise, evaluate and set into context some of the new insights arising from these studies and also to discuss some considerations to be taken into account in future research activities.
Simon Brewer, Yves Bergeron, Christelle Hely-Alleaume, Adam A. Ali, Christopher Carcaillet, Martin-Philippe Girardin. Eastern boreal North American wildfire risk of the past 7000 years: A model-data comparison. 2010. Geophysical Research Letters 37, L14709
DOI : 10.1029/2010GL043706
We present here a 7000-year wildfire reconstruction based on sedimentary charcoal series from five lakes located south of Hudson Bay in eastern boreal North America. The reconstruction shows a significant downward trend in the frequency of large fires from 0.0061 fire·yr−1 ca. 5000 cal yr BP to 0.0033 fire·yr−1 at present. Simulations of fire-season climate based on UK Universities Global Atmospheric Modelling Programme output and reconstructions based on proxy data both indicate a shift toward increasing available moisture in the region between the mid-Holocene and today. We infer that the diminishing trend in wildfire activity was ultimately caused by the steady orbitally driven reduction in summer insolation. Future higher temperatures not compensated for by significant precipitation increases will bring fire frequency back toward its upper limit, recorded between 6000 and 2000 cal yr BP.
Manfred Mudelsee, Yves Bergeron, Adam A. Ali, Christelle Hely-Alleaume, Christopher Carcaillet, Igor Drobyshev, Martin-Philippe Girardin. Heterogeneous response of circumboreal wildfire risk to climate change since the early 1900s. 2009. Global Change Biology 15(11):2751–2769
DOI : 10.1111/j.1365-2486.2009.01869.x
We investigated changes in wildfire risk over the 1901−2002 (ad) period with an analysis of broad-scale patterns of July monthly drought code (MDC) variability on 28 forested ecoregions of the North American and Eurasian continents. The MDC is an estimate of the net effect of changes in evapotranspiration and precipitation on cumulative moisture depletion in soils, and is well correlated with annual fire statistics across the circumboreal (explaining 25–61% of the variance in regional area burned). We used linear trend and regime shift analyses to investigate (multi-) decadal changes in MDC and percentage area affected by drought, and kernel function for analysis of temporal changes in the occurrence rates of extreme drought years. Our analyses did not reveal widespread patterns of linear increases in dryness through time as a response to rising Northern Hemisphere land temperatures. Instead, we found heterogeneous patterns of drought severity changes that were inherent to the nonuniformly distributed impacts of climate change on dryness. Notably, significant trends toward increasing summer moisture in southeastern and southwestern boreal Canada were detected. The diminishing wildfire risk in these regions is coherent with widely reported decreases in area burned since about 1850, as reconstructed by dendrochronological dating of forest stands. Conversely, we found evidence for increasing percentage area affected by extreme droughts in Eurasia (+0.57% per decade; P<0.05) and occurrence rates of extreme drought years in Eurasian taiga (centered principally on the Okhotsk–Manchurian taiga, P=0.07). Although not statistically significant, temporal changes in occurrence rates are sufficiently important spatially to be paid further attention. The absence of a linear trend in MDC severity, in conjunction with the presence of an increase in the occurrence rate of extreme drought years, suggest that fire disturbance regimes in the Eurasian taiga could be shifting toward being increasingly pulse dependent.
Manfred Mudelsee, Yves Bergeron, Christelle Hely-Alleaume, Adam A. Ali, Christopher Carcaillet, Martin-Philippe Girardin, Igor Drobyshev. Heterogeneous response of circumboreal wildfire risk to climate change since the early 1900s. 2009. Global Change Biology 1-19.
DOI : 10.1111/j.1365-2486.2009.01869.x
We investigated changes in wildfire risk over the 19012002 (AD) period with an analysis
of broad-scale patterns of July monthly drought code (MDC) variability on 28 forested
ecoregions of the North American and Eurasian continents. The MDC is an estimate of
the net effect of changes in evapotranspiration and precipitation on cumulative moisture
depletion in soils, and is well correlated with annual fire statistics across the circumboreal
(explaining 25–61% of the variance in regional area burned).We used linear trend and
regime shift analyses to investigate (multi-) decadal changes in MDC and percentage
area affected by drought, and kernel function for analysis of temporal changes in the
occurrence rates of extreme drought years. Our analyses did not reveal widespread
patterns of linear increases in dryness through time as a response to rising Northern
Hemisphere land temperatures. Instead, we found heterogeneous patterns of drought
severity changes that were inherent to the nonuniformly distributed impacts of climate
change on dryness. Notably, significant trends toward increasing summer moisture in
southeastern and southwestern boreal Canada were detected. The diminishing wildfire
risk in these regions is coherent with widely reported decreases in area burned since
about 1850, as reconstructed by dendrochronological dating of forest stands. Conversely,
we found evidence for increasing percentage area affected by extreme droughts in
Eurasia (10.57% per decade; Po0.05) and occurrence rates of extreme drought years in
Eurasian taiga (centered principally on the Okhotsk–Manchurian taiga, P50.07).
Although not statistically significant, temporal changes in occurrence rates are sufficiently
important spatially to be paid further attention. The absence of a linear trend in
MDC severity, in conjunction with the presence of an increase in the occurrence rate of
extreme drought years, suggest that fire disturbance regimes in the Eurasian taiga could
be shifting toward being increasingly pulse dependent.
Adam A. Ali, Yves Bergeron, Christopher Carcaillet. Long-term fire frequency variability in the eastern
Canadian boreal forest: the influences of climate
vs. local factors. 2009. Global Change Biology 1-12.
DOI : 10.1111/j.1365-2486.2009.01842.x
The influence of climatic and local nonclimatic factors on the fire regime of the eastern
Canadian boreal forest over the last 8000 years is investigated by examining charred
particles preserved in four lacustrine deposits. Herein, we compare the distribution of
fire-free intervals (FFIs) and the synchronicity of fire events among sites, using Ripley’s
K-function to determine the extent of the role of local-scale vs. large-scale processes with
respect to fire control. Between 8000 and 5800 cal. BP (calibrated years before present) the
climatic and ecological conditions were less conducive to fire events than after this date.
After 5800 cal. BP, the number of fires per 1000 years (fire frequency) progressively increased,
reaching a maximum ca. 3400 cal. BP. There was a sharp decrease in fire frequency
during the last 800 years. Between 8000 and 4000 cal. BP, comparable FFIs and synchronous
fire episodes were determined for the study sites. During this period, the fire
frequency was predominantly controlled by climate. After 4000 cal. BP, two sites displayed
independent fire histories (different FFI distributions or asynchronous fire
events), underlining the important influence of local factors, including short-term fuel
wetness, characteristics of the watershed and landscape connectivity, in determining fire
occurrence. We conclude that climatic changes occurred during the last 4000 years that
induced a rise in the water table; this may explain the high spatial heterogeneity in fire
history. Current and projected global climatic changes may cause similar spatial variability
in fire frequency.
Adam A. Ali, Alain Larouche, Yves Bergeron, Pierre J.H. Richard, Hugo Asselin, Christopher Carcaillet. Changes in fire regime explain the
Holocene rise and fall of Abies
balsamea in the coniferous forests of
western Québec, Canada. 2008. Holocene 18(5):693-703.
DOI : 10.1177/0959683608091780
The coniferous boreal forest of northeastern North America is characterized by large and severe fire
events and dominated by black spruce (Picea mariana), with scattered patches of balsam fir (Abies balsamea),
a species otherwise predominant in the more southern mixedwood boreal forests, characterized by smaller and
less severe fire events. Because balsam fir is a late-successional species ill-adapted to fire, this study aimed at
determining if the scattered balsam-fir patches found in the coniferous forest were relics of a former fire regime
characterized by less frequent and/or severe conflagrations. Fire and vegetation history were assessed for a
coniferous forest site through analyses of charcoal, pollen and plant macroremains preserved in lake sediments,
peat and hydromorphic forest soil. Pollen and macroremains analyses show that black spruce dominated the
local vegetation since deglaciation (c. 8000 cal. yr BP). Balsam fir was abundant around the site during the
warm and humid summers of the Hypsithermal (between c. 7000 and 3500 cal. yr BP), before gradually declining
during the cool and dry Neoglacial, which was characterized by increased fire frequency and severity.
Scattered balsam fir patches in the coniferous forest result from the fragmentation of formerly larger populations
and are presently in disequilibrium with climate.© 2008 SAGE publications. All rights reserved.
voir les plus récentes
Marion Blache, Dorian Gaboriau, Hugo Asselin, Sébastien Joannin, Jean-Sepet Mathis, Martin-Philippe Girardin, Pierre J.H. Richard, Yves Bergeron, Adam A. Ali. Holocene rise and fall of pine in Quebec's northern temperate forest was controlled by fire 26e colloque de la Chaire AFD. Hôtel Forestel, Val-d'Or, Québec. (2024-11-20)
Dorian Gaboriau, Marianne Vogel, Jordan Paillard, Hugo Asselin, Adam A. Ali, Yves Bergeron. Histoire à long terme de la dynamique de la végétation et des incendies aux plus hautes altitudes du nord-ouest du Québec, Canada 17e colloque annuel du CEF, Université du Québec en Outaouais (2024-05-02)
Adam A. Ali Les incendies dans les écosystèmes boréaux : causes et conséquences Axe écologie UQAM (2024-02-21)
Marianne Vogel, Adam A. Ali, Sébastien Joannin, Yves Bergeron, Hugo Asselin. Facilitation de la migration postglaciaire végétale par les avant-postes insulaires d’un lac proglaciaire en Amérique du Nord-Est. 3e rencontre annuelle du Laboratoire International de Recherche sur les Forêts Froides. Station touristique Duchesnay, Québec. (2023-10-03)
Marion Lacand, Hugo Asselin, Damien Rius, Marianne Vogel, Adam A. Ali. Les feux peuvent-ils induire des épisodes d'érosion dans les bassins versants du nord de la Finlande ? 3e rencontre annuelle du Laboratoire International de Recherche sur les Forêts Froides. Station touristique Duchesnay, Québec. (2023-10-03)
Marianne Vogel, Sébastien Joannin, Adam A. Ali, Yves Bergeron, Edith Leclerc, Cécile Latapy, Hugo Asselin. Les premières étapes de la végétation d’anciennes îles du lac Ojibway (Abitibi, Québec) au début de l’Holocène 16e colloque annuel du CEF, Université de Montréal (2023-05-08)
Marianne Vogel, Adam A. Ali, Hugo Asselin, Sabrina Leclercq, Cécile Latapy, Sébastien Joannin, Yves Bergeron. Histoire des paléo-îles du lac proglaciaire Ojibway
(Abitibi, Québec)
premières étapes de la végétation 24e colloque de la Chaire AFD. Université du Québec en Abitibi-Témiscamingue, Rouyn-Noranda, Québec. (2022-11-22)
Adam A. Ali Les feux dans les écosystèmes boréaux : causes et conséquences Midi-foresterie (2021-10-26)
Marianne Vogel, Hugo Asselin, Adam A. Ali, Yves Bergeron, Sébastien Joannin. L'histoire des paléo-îles du lac proglaciaire Ojibway (Abitibi) 21e colloque de la Chaire AFD. Université du Québec en Abitibi-Témiscamingue, Rouyn-Noranda, Québec. (2019-11-30)
Bi-Tchoko Vincent Evrard Kouadio, Yves Bergeron, Olivier Blarquez, Christelle Hely-Alleaume, Adam A. Ali. Affiche 9
Des outils pour caractériser les différents types de pessières afin de reconstruire et de comprendre leur dynamique à long terme au Canada. 20e colloque de la Chaire AFD. Université du Québec en Abitibi-Témiscamingue, Lorrainville, Québec. (2018-11-30)
Samira Ouarmim, Hugo Asselin, Adam A. Ali, Christelle Hely-Alleaume, Yves Bergeron. 8000 ans d'histoire et très peu de feux en forêt boréale mixte 14e colloque de la Chaire AFD. Université du Québec en Abitibi-Témiscamingue, Rouyn-Noranda, Québec. (2012-11-29)
Adam A. Ali Feux et dynamiques post-glaciaires de Abies balsamea dans la forêt boréale coniférienne (Nord du Québec) : analyses à haute résolution de charbons de bois et de macrorestes végétaux. Feux et dynamiques post-glaciaires de Abies balsam (2006-02-28)
Faustine Machut, Dorian Gaboriau, Yves Bergeron, Adam A. Ali, Carsten Meyer-Jacob. Effets à long terme des feux de forêt sur la qualité de l'eau dans les lacs de la Forêt d’Enseignement et de Recherche du Lac Duparquet (FERLD), Abitibi-Témiscamingue, Québec, Canada. 26e colloque de la Chaire AFD. Hôtel Forestel, Val-d'Or, Québec.