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Research Project
FRISCO: managing Fire-induced RISks of water quality Contamination
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Publications
How do large wildfires impact sediment redistribution over multiple decades?
Publication . Follmi, Dante; Baartman, Jantiene; Benali, Akli; Nunes, João Pedro
Wildfires have become an increasing threat for Mediterranean ecosystems, due to increasing climate change-induced wildfire activity and changing land management practices. In addition to the initial risk, wildfires can alter the soil in various ways—depending on fire severity—and cause enhanced post-fire erosion. Usually, post-fire erosion studies focus on a short time window and lack the attention for sediment dynamics at larger spatial scales. Yet, these large spatial and temporal scales are fundamental for a better understanding of long-term destructive effects of multiple recurring wildfires on post-fire erosion processes and catchment sediment dynamics. In this study the landscape evolution model LAPSUS was used to simulate erosion and deposition in the 404 km2 Águeda catchment in north-central Portugal over a 41-year (1979–2020) timespan, including eight wildfires each burning >1000 ha. To include variation in fire severity and its impact on the soil, four burn severity classes, represented by the difference normalized burn ratio (dNBR), were parameterized. Although model calibration was difficult due to lack of spatial and temporal measured data, the results show that long-term post-fire net erosion rates were significantly higher in the wildfire scenarios (5.95 ton ha−1 yr−1) compared to those of a non-wildfire scenario (0.58 ton ha−1 yr−1). Furthermore, erosion values increased with burn severity and multiple wildfires increased the overall catchment sediment build-up. Simulated erosion patterns showed great spatial variability, with large deposition and erosion rates inside streams. This variability made it difficult to identify land uses that were most sensitive for post-fire erosion, because some land uses were located in more erosion-sensitive areas (e.g. streams, gullies) or were more affected by high burn severity levels than others. Despite these limitations, LAPSUS performed well on addressing spatial sediment processes and can contribute to pre-fire management strategies, by identifying locations at risk of post-fire erosion.
Assessing impacts of future climate change on extreme fire weather and pyro-regions in Iberian Peninsula
Publication . Menezes, Tomás; Pereira, M.G.; Nunes, João Pedro
Weather conditions play an important role in wildfire activity. In many regions, future climate could lead to different fire weather, with impacts on the ignition, behaviour, and suppression of wildfires, which may, therefore, force new fire regimes. This study aimed to assess the evolution of fire weather indices and the Number of Extreme Days (NED) in the context of climate change. We estimated the impact of these changes on monthly Normalized Burnt Area (NBA) and in the spatial distribution of Pyro-Regions (PR), using a recently identified relationship between NED and NBA intra-annual patterns. The components of the Canadian Forest Fire Weather Index System (CFFWIS) in the Iberian Peninsula were analysed for present-day conditions and future climate scenarios, using daily data from ERA-Interim (1980-2014) and an ensemble of simulations from 11 EURO-CORDEX high spatial resolution models, for two future periods (2041-2070 and 2071-2100) and scenarios (RCP4.5 and RCP8.5). Results suggest a significant increase in future fire weather risk, especially in late spring and early autumn, and also in southern and eastern Iberian Peninsula. NED is expected to strongly increase in summer months in the four PRs, but also to decrease in March and April in the northwestern and southwestern PR. This could change the spatial distribution of PRs, with a general northwards movement: the northern PR is expected to disappear except north of the Cantabrian Mountains, being replaced by the northwestern PR; the southwestern PR is expected to grow and occupy part of the area currently in the northwestern PR; and a new PR could appear in parts of the current eastern PR. These PR changes follow the projected modifications in the major climate regions. Results suggest different fire regimes in the future, with higher fire weather risk, and a longer and harsher fire season.
A method to produce a flexible and customized fuel models dataset
Publication . Sá, A.C.L.; Benali, A.; Aparicio, B.A.; Bruni, C.; Mota, C.; Pereira, J.M.C.; Fernandes, P.M.
Simulation of vegetation fires very often resorts to fire-behavior models that need fuel models as
input. The lack of fuel models is a common problem for researchers and fire managers because
its quality depends on the quality/availability of data. In this study we present a method that
combines expert- and research-based knowledge with several sources of data (e.g. satellite and
fieldwork) to produce customized fuel models maps. Fuel model classes are assigned to land cover
types to produce a basemap, which is then updated using empirical and user-defined rules. This
method produces a map of surface fuel models as detailed as possible. It is reproducible, and
its flexibility relies on juxtaposing independent spatial datasets, depending on their quality or
availability. This method is developed in a ModelBuilder/ArcGis toolbox named FUMOD that
integrates ten sub-models. FUMOD has been used to map the Portuguese annual fuel models
grids since 2019, supporting regional fire risk assessments and suppression decisions. Datasets,
models and supplementary files are available in a repository (https://github.com/anasa30/PT_
FuelModels).
Comparing the impacts of wildfire and meteorological variability on hydrological and erosion responses in a Mediterranean catchment
Publication . Wu, Jinfeng; Baartman, Jantiene; Nunes, João Pedro
Drivers of extreme burnt area in Portugal: fire weather and vegetation
Publication . Menezes, Tomás; Benali, Akli; Pereira, Mário Gonzalez; Silva, João M. N.; Nunes, João Pedro
Fire weather indices are used to assess the effect
of weather on wildfire behaviour and to support fire management. Previous studies identified the high daily severity
rating percentile (DSRp) as being strongly related to the total burnt area (BA) in Portugal, but it is still poorly understood how this knowledge can support fire management at a
smaller spatial scale. The aims of this study were to (1) assess whether the 90th DSRp (DSR90p) threshold is adequate
for estimating most of the BA in mainland Portugal; (2) analyse the spatial variability of the DSRp threshold that explains
a large part of BA, at higher resolution; and, (3) analyse
whether vegetation cover can justify the DSRp spatial variability.
We used weather reanalysis data from ERA5-Land, wildfire and land use data from Portuguese land management departments for an extended summer period (15 May to 31 October) from 2001 to 2019. We computed and related DSRp
to large wildfires (BA > 100 ha) and land use to clarify the
effectiveness of the DSRp for estimating BA in Portugal and
assess how vegetation influences it.
Results revealed that the DSR90p is an adequate indicator
of extreme fire weather days and BA in Portugal. In addition, the spatial pattern of the DSRp associated with most of
the total BA shows variability at the municipality scale. Municipalities where large wildfires occur with more extreme
weather conditions have most of the BAs in forests and are
in coastal areas. By contrast, municipalities where large wild fires occur with less extreme weather conditions are predominantly covered by shrublands and are situated in eastern and
inland regions. These findings are a novelty for fire science
in Portugal and should be considered by fire managers and
fire risk assessors.
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Funders
Funding agency
Fundação para a Ciência e a Tecnologia
Funding programme
3599-PPCDT
Funding Award Number
PCIF/MPG/0044/2018