Your search keyword '"Werf, Guido R."' showing total 8 results

1. The role of fire in global forest loss dynamics

Author

Wees, Dave, Werf, Guido R, Randerson, James T, Andela, Niels, Chen, Yang, and Morton, Douglas C

Subjects

Ecological Applications, Environmental Sciences, Life on Land, Africa, Ecosystem, Fires, Forests, Humans, Indonesia, Trees, active fires, burned area, deforestation, fire, forest loss, satellite data, tree mortality, Biological Sciences, Ecology, Biological sciences, Earth sciences, Environmental sciences

Abstract

Fires, among other forms of natural and anthropogenic disturbance, play a central role in regulating the location, composition and biomass of forests. Understanding the role of fire in global forest loss is crucial in constraining land-use change emissions and the global carbon cycle. We analysed the relationship between forest loss and fire at 500 m resolution based on satellite-derived data for the 2003-2018 period. Satellite fire data included burned area and active fire detections, to best account for large and small fires, respectively. We found that, on average, 38 ± 9% (± range) of global forest loss was associated with fire, and this fraction remained relatively stable throughout the study period. However, the fraction of fire-related forest loss varied substantially on a regional basis, and showed statistically significant trends in key tropical forest areas. Decreases in the fraction of fire-related forest loss were found where deforestation peaked early in our study period, including the Amazon and Indonesia while increases were found for tropical forests in Africa. The inclusion of active fire detections accounted for 41%, on average, of the total fire-related forest loss, with larger contributions in small clearings in interior tropical forests and human-dominated landscapes. Comparison to higher-resolution fire data with resolutions of 375 and 20 m indicated that commission errors due to coarse resolution fire data largely balanced out omission errors due to missed small fire detections for regional to continental-scale estimates of fire-related forest loss. Besides an improved understanding of forest dynamics, these findings may help to refine and separate fire-related and non-fire-related land-use change emissions in forested ecosystems.

Published

2021

2. The role of fire in global forest loss dynamics.

Author

van Wees, Dave, van der Werf, Guido R, Randerson, James T, Andela, Niels, Chen, Yang, and Morton, Douglas C

Subjects

Humans, Trees, Fires, Ecosystem, Africa, Indonesia, Forests, active fires, burned area, deforestation, fire, forest loss, satellite data, tree mortality, Environmental Sciences, Biological Sciences, Ecology

Abstract

Fires, among other forms of natural and anthropogenic disturbance, play a central role in regulating the location, composition and biomass of forests. Understanding the role of fire in global forest loss is crucial in constraining land-use change emissions and the global carbon cycle. We analysed the relationship between forest loss and fire at 500 m resolution based on satellite-derived data for the 2003-2018 period. Satellite fire data included burned area and active fire detections, to best account for large and small fires, respectively. We found that, on average, 38 ± 9% (± range) of global forest loss was associated with fire, and this fraction remained relatively stable throughout the study period. However, the fraction of fire-related forest loss varied substantially on a regional basis, and showed statistically significant trends in key tropical forest areas. Decreases in the fraction of fire-related forest loss were found where deforestation peaked early in our study period, including the Amazon and Indonesia while increases were found for tropical forests in Africa. The inclusion of active fire detections accounted for 41%, on average, of the total fire-related forest loss, with larger contributions in small clearings in interior tropical forests and human-dominated landscapes. Comparison to higher-resolution fire data with resolutions of 375 and 20 m indicated that commission errors due to coarse resolution fire data largely balanced out omission errors due to missed small fire detections for regional to continental-scale estimates of fire-related forest loss. Besides an improved understanding of forest dynamics, these findings may help to refine and separate fire-related and non-fire-related land-use change emissions in forested ecosystems.

Published

2021

3. Forecasting Global Fire Emissions on Subseasonal to Seasonal (S2S) Time Scales.

Author

Chen, Yang, Randerson, James T., Coffield, Shane R., Foufoula‐Georgiou, Efi, Smyth, Padhraic, Graff, Casey A., Morton, Douglas C., Andela, Niels, Werf, Guido R., Giglio, Louis, and Ott, Lesley E.

Subjects

FIRE, SMOKE, FIRE management, BOX-Jenkins forecasting, FIRE weather, EL Nino

Abstract

Fire emissions of gases and aerosols alter atmospheric composition and have substantial impacts on climate, ecosystem function, and human health. Warming climate and human expansion in fire‐prone landscapes exacerbate fire impacts and call for more effective management tools. Here we developed a global fire forecasting system that predicts monthly emissions using past fire data and climate variables for lead times of 1 to 6 months. Using monthly fire emissions from the Global Fire Emissions Database (GFED) as the prediction target, we fit a statistical time series model, the Autoregressive Integrated Moving Average model with eXogenous variables (ARIMAX), in over 1,300 different fire regions. Optimized parameters were then used to forecast future emissions. The forecast system took into account information about region‐specific seasonality, long‐term trends, recent fire observations, and climate drivers representing both large‐scale climate variability and local fire weather. We cross‐validated the forecast skill of the system with different combinations of predictors and forecast lead times. The reference model, which combined endogenous and exogenous predictors with a 1 month forecast lead time, explained 52% of the variability in the global fire emissions anomaly, considerably exceeding the performance of a reference model that assumed persistent emissions during the forecast period. The system also successfully resolved detailed spatial patterns of fire emissions anomalies in regions with significant fire activity. This study bridges the gap between the efforts of near‐real‐time fire forecasts and seasonal fire outlooks and represents a step toward establishing an operational global fire, smoke, and carbon cycle forecasting system. Plain Language Summary: Global fire risk is expected to increase in the future, and effective fire forecast and management tools are needed. Here we developed a statistical forecasting system that can predict global fire emissions with lead times of 1 to 6 months. The modeling system recognizes that future fire activity in many regions is related to fire activity in preceding months, as well as climate variables. By comparing predicted results with observations, we showed our modeling system performed reasonably well in reproducing the temporal and spatial variability of fire emissions. We believe this system can be integrated into an operational global fire, smoke, and carbon forecasting system to better anticipate periods of high and low fire activity on subseasonal to seasonal time scales. Key Points: We developed a global fire emissions forecasting system with lead times of 1 to 6 months, building on a statistical ARIMAX modeling frameworkThe system draws upon different data sources to optimize fire prediction in over 1,300 individual fire cohesive regionsOur results suggested that the joint use of past fire observations within the fire season and climate data can improve S2S fire prediction [ABSTRACT FROM AUTHOR]

Published

2020

4. Modelling biomass burning emissions and the effect of spatial resolution: a case study for Africa based on the Global Fire Emissions Database (GFED).

Author

van Wees, Dave and van der Werf, Guido R.

Subjects

*BIOMASS burning, *LAND cover, *ENERGY consumption, *PARTICLE emissions, *FIRE, *DATA reduction

Abstract

Large-scale fire emission estimates may be influenced by the spatial resolution of the model and input datasets used. Especially in areas with relatively heterogeneous land cover, a coarse model resolution might lead to substantial errors in estimates. We developed a model using MODerate resolution Imaging Spectroradiometer (MODIS) satellite observations of burned area and vegetation characteristics to study the impact of spatial resolution on modelled fire emission estimates. We estimated fire emissions for sub-Saharan Africa at 500 m spatial resolution (native MODIS burned area) for the 2002–2017 period, using a simplified version of the Global Fire Emissions Database (GFED) modelling framework, and compared this to model runs at a range of coarser resolutions (0.050, 0.125, 0.250 ∘). We estimated fire emissions of 0.68 Pg C yr -1 at 500 m resolution and 0.82 Pg C yr -1 at 0.25 ∘ resolution; a difference of 24 %. At 0.25 ∘ resolution, our model results were relatively similar to GFED4, which also runs at 0.25 ∘ resolution, whereas our 500 m estimates were substantially lower. We found that lower emissions at finer resolutions are mainly the result of reduced representation errors when comparing modelled estimates of fuel load and consumption to field measurements, as part of the model calibration. Additional errors stem from the model simulation at coarse resolution and lead to an additional 0.02 Pg C yr -1 difference in estimates. These errors exist due to the aggregation of quantitative and qualitative model input data; the average- or majority- aggregated values are propagated in the coarse-resolution simulation and affect the model parameterization and the final result. We identified at least three error mechanisms responsible for the differences in estimates between 500 m and 0.25 ∘ resolution simulations, besides those stemming from representation errors in the calibration process, namely (1) biome misclassification leading to errors in parameterization, (2) errors due to the averaging of input data and the associated reduction in variability, and (3) a temporal mechanism related to the aggregation of burned area in particular. Even though these mechanisms largely neutralized each other and only modestly affect estimates at a continental scale, they lead to substantial error at regional scales with deviations of up to a factor 4 and may affect large-scale estimates differently for other continents. These findings could prove valuable in improving coarse-resolution models and suggest the need for increased spatial resolution in global fire emission models. [ABSTRACT FROM AUTHOR]

Published

2019

5. The Global Fire Atlas of individual fire size, duration, speed and direction.

Author

Andela, Niels, Morton, Douglas C., Giglio, Louis, Paugam, Ronan, Chen, Yang, Hantson, Stijn, van der Werf, Guido R., and Randerson, James T.

Subjects

FIRE, FIRE management, EARTH system science, BIOMASS burning, ATMOSPHERIC composition, BIOGEOCHEMICAL cycles, REMOTE-sensing images, LAND management

Abstract

Natural and human-ignited fires affect all major biomes, altering ecosystem structure, biogeochemical cycles and atmospheric composition. Satellite observations provide global data on spatiotemporal patterns of biomass burning and evidence for the rapid changes in global fire activity in response to land management and climate. Satellite imagery also provides detailed information on the daily or sub-daily position of fires that can be used to understand the dynamics of individual fires. The Global Fire Atlas is a new global dataset that tracks the dynamics of individual fires to determine the timing and location of ignitions, fire size and duration, and daily expansion, fire line length, speed, and direction of spread. Here, we present the underlying methodology and Global Fire Atlas results for 2003–2016 derived from daily moderate-resolution (500 m) Collection 6 MCD64A1 burned-area data. The algorithm identified 13.3 million individual fires over the study period, and estimated fire perimeters were in good agreement with independent data for the continental United States. A small number of large fires dominated sparsely populated arid and boreal ecosystems, while burned area in agricultural and other human-dominated landscapes was driven by high ignition densities that resulted in numerous smaller fires. Long-duration fires in boreal regions and natural landscapes in the humid tropics suggest that fire season length exerts a strong control on fire size and total burned area in these areas. In arid ecosystems with low fuel densities, high fire spread rates resulted in large, short-duration fires that quickly consumed available fuels. Importantly, multiday fires contributed the majority of burned area in all biomass burning regions. A first analysis of the largest, longest and fastest fires that occurred around the world revealed coherent regional patterns of extreme fires driven by large-scale climate forcing. Global Fire Atlas data are publicly available through http://www.globalfiredata.org (last access: 9 August 2018) and 10.3334/ORNLDAAC/1642, and individual fire information and summary data products provide new information for benchmarking fire models within ecosystem and Earth system models, understanding vegetation–fire feedbacks, improving global emissions estimates, and characterizing the changing role of fire in the Earth system. [ABSTRACT FROM AUTHOR]

Published

2019

6. Long-term trends and interannual variability of forest, savanna and agricultural fires in South America.

Author

Chen, Yang, Morton, Douglas C, Jin, Yufang, Collatz, G James, Kasibhatla, Prasad S, van der Werf, Guido R, DeFries, Ruth S, and Randerson, James T

Subjects

FIRE, FIRE management, SAVANNAS, TROPICAL forests, FOREST fires, ENVIRONMENTAL engineering, FIRES, THROUGHFALL

Abstract

Background: Landscape fires in South America have considerable impacts on ecosystems, air quality and the climate system. We examined long-term trends and interannual variability of forest, savanna and agricultural fires for the continent during 2001–2012 using multiple satellite-derived fire products. Results: The annual number of active fires in tropical forests increased significantly during 2001–2005. Several satellite-derived metrics, including fire persistence, indicated that this trend was mostly driven by deforestation. Fires between 2005 and 2012 had a small decreasing trend and large year-to-year changes that were associated with climate extremes. Fires in savannas and evergreen forests increased in parallel during drought events in 2005, 2007 and 2010, suggesting similar regional climate controls on fire behavior. Deforestation fire intensity (the number of fires per unit of deforested area) increased significantly within the Brazilian Amazon in areas with small-scale deforestation. Conclusion: Fires associated with forest degradation are becoming an increasingly important component of the fire regime and associated carbon emissions. [ABSTRACT FROM AUTHOR]

Published

2013

7. Continental-Scale Partitioning of Fire Emissions During the1997 to 2001 El Niño/La Niña Period.

Author

Werf, Guido R. van der, Randerson, James T., Collate, C. James, Ciglio, Louis, Kasibhatla, Prasad S., Arellano Jr., Avelino F., Olsen, Seth C., and Kasischke, Eric S.

Subjects

*FIRE, *DROUGHTS, *CARBON dioxide, *ATMOSPHERIC methane, *GREENHOUSE effect, *BIOGEOCHEMICAL cycles

Abstract

During the 1997 to 1998 El Nino, drought conditions triggered widespread increases in fire activity, releasing CH[sub4] and CO[sub2] to the atmosphere. We evaluated the contribution of fires from different continents to variability in these greenhouse gases from 1997 to 2001, using satellite-based estimates of fire activity, biogeochemical modeling, and an inverse analysis of atmospheric CO anomalies. During the 1997 to 1998 El Nino, the fire emissions anomaly was 2.1 ± 0.8 petagrams of carbon, or 66 ± 24% of the CO[sub2] growth rate anomaly. The main contributors were Southeast Asia (60%), Central and South America (30%), and boreal regions of Eurasia and North America (10%). [ABSTRACT FROM AUTHOR]

Published

2004

8. Historical background and current developments for mapping burned area from satellite Earth observation.

Author

Chuvieco, Emilio, Mouillot, Florent, van der Werf, Guido R., San Miguel, Jesús, Tanase, Mihai, Koutsias, Nikos, García, Mariano, Yebra, Marta, Padilla, Marc, Gitas, Ioannis, Heil, Angelika, Hawbaker, Todd J., and Giglio, Louis

Subjects

*ARTIFICIAL satellites, *FIRE management, *BIOGEOCHEMICAL cycles, *REMOTE sensing, *AIR quality

Abstract

Fire has a diverse range of impacts on Earth's physical and social systems. Accurate and up to date information on areas affected by fire is critical to better understand drivers of fire activity, as well as its relevance for biogeochemical cycles, climate, air quality, and to aid fire management. Mapping burned areas was traditionally done from field sketches. With the launch of the first Earth observation satellites, remote sensing quickly became a more practical alternative to detect burned areas, as they provide timely regional and global coverage of fire occurrence. This review paper explores the physical basis to detect burned area from satellite observations, describes the historical trends of using satellite sensors to monitor burned areas, summarizes the most recent approaches to map burned areas and evaluates the existing burned area products (both at global and regional scales). Finally, it identifies potential future opportunities to further improve burned area detection from Earth observation satellites. • A review of burned area trends in past 40 years of RS is performed. • Different sensors used for BA mapping presented, including Radar and Lidar. • Main burned area products are commented [ABSTRACT FROM AUTHOR]

Published

2019