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Remote Sensing, Vol. 11, Pages 764: Translating Fire Impacts in Southwestern Amazonia into Economic Costs (2019)

Wesley A. Campanharo, Aline P. Lopes, Liana O. Anderson, Thiago F. M. R. da Silva, Luiz E. O. C. Aragão

MDPI

In: Remote Sensing

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Publication Date: 2019

Description: Between 1998 and 2017, climate-related disasters represented 91% of all occurrences worldwide, causing approximately US$ 2.245 billion of direct economic losses. In the Amazon region, fire is used as a widely spread technique for land clearing, agricultural management, hunting, and religious rituals. However, over the past 20 years, severe droughts caused a major amplification of fire occurrences, leading to several socioeconomic and environmental impacts. Particularly in Acre state, located in the southwestern Brazilian Amazon, the occurrence of extensive fires, associated with extreme climatic events, has been reported since 2005. However, fire dynamics, land tenure relationships, and associated impacts are poorly quantified. In this study, we aim to investigate the following: (1) The spatiotemporal variability of fire dynamics during anomalously dry and regular climate conditions; (2) the attribution of fire occurrence and land tenure relationship, and (3) the environmental, social, and economic impacts caused by fires and its consequences for Acre’s economy. We analyzed information on the spatial patterns of fire, its direct impacts on land use and land cover, carbon stocks, CO2 emissions, the indirect impact on human illness, and finally the costs of these impacts from 2008 to 2012. During the studied period, burned areas were concentrated around the major cities and roads, forming polygons up to 0.6 km2. However, in 2010, an extremely dry year, fires spread to remote areas, impacting protected private areas and sustainable-use conservation areas. In 2010, the total area affected by forest fires was approximately 16 times greater than in meteorologically normal years. The total economic loss estimated in 2010 was around US$ 243.36 ± 85.05 million and for the entire period, US$ 307.46 ± 85.41 million. These values represent 7.03 ± 2.45% and 9.07 ± 2.46% of Acre’s gross domestic product (GDP), respectively.

Electronic ISSN: 2072-4292

Topics: Architecture, Civil Engineering, Surveying , Geography

Published by MDPI

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Remote Sensing, Vol. 4, Pages 1245-1271: Biome-Scale Forest Properties in Amazonia Based on Field and Satellite Observations (2012)

Liana O. Anderson

MDPI Publishing

In: Remote Sensing

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Publication Date: 2012-05-05

Description: Amazonian forests are extremely heterogeneous at different spatial scales. This review intends to present the large-scale patterns of the ecosystem properties of Amazonia, and focuses on two parts of the main components of the net primary production: the long-lived carbon pools (wood) and short-lived pools (leaves). First, the focus is on forest biophysical properties, and secondly, on the macro-scale leaf phenological patterns of these forests, looking at field measurements and bringing into discussion the recent findings derived from remote sensing dataset. Finally, I discuss the results of the three major droughts that hit Amazonia in the last 15 years. The panorama that emerges from this review suggests that slow growing forests in central and eastern Amazonia, where soils are poorer, have significantly higher above ground biomass and higher wood density, trees are higher and present lower proportions of large-leaved species than stands in northwest and southwest Amazonia. However, the opposite pattern is observed in relation to forest productivity and dynamism, which is higher in western Amazonia than in central and eastern forests. The spatial patterns on leaf phenology across Amazonia are less marked. Field data from different forest formations showed that new leaf production can be unrelated to climate seasonality, timed with radiation, timed with rainfall and/or river levels. Oppositely, satellite images exhibited a large-scale synchronized peak in new leaf production during the dry season. Satellite data and field measurements bring contrasting results for the 2005 drought. Discussions on data processing and filtering, aerosols effects and a combined analysis with field and satellite images are presented. It is suggested that to improve the understanding of the large-scale patterns on Amazonian forests, integrative analyses that combine new technologies in remote sensing and long-term field ecological data are imperative.

Electronic ISSN: 2072-4292

Topics: Architecture, Civil Engineering, Surveying , Geography

Published by MDPI Publishing

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APPLICATION OF REMOTE SENSING TO UNDERSTANDING FIRE REGIMES AND BIOMASS BURNING EMISSIONS OF THE TROPICAL ANDES (2014)

Immaculada Oliveras, Liana O. Anderson, Yadvinder Malhi

Wiley

In: Global Biogeochemical Cycles

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Publication Date: 2014-03-28

Description: In the tropical Andes, fires play an important cultural and ecological role. However, there have been very few systematic studies aimed at understanding the biomass burning dynamics in the area. This paper seeks to advance on our understanding of burning regimes in this region, with the first detailed and comprehensive assessment of fire occurrence and the derived gross biomass burning emissions of an area of the Peruvian tropical Andes. We selected for analysis an area of 2.8 million hectares at altitudes over 2000 m. We analyzed fire occurrence over a 12-year period with three types of satellite data: active fire pixels from the MODerate Resolution Imaging Spectroradiometer (MODIS) MCD14ML product, burned area scars from the MODIS MCD45 product, and higher resolution Landsat 5 TM imagery. Fire dynamics showed a large intra- and inter-annual variability, with most fires occurring May-October (the period coinciding with the dry season), and year 2005 having the largest number of fires and burned area. Total area burned decreased with increasing rainfall until a given rainfall threshold beyond which no relationship was found. The estimated fire return interval (FRI) for the area is 37 years for grasslands, which is within the range reported for grasslands and 65 years for forests, which is remarkably shorter than other reported FRI in tropical moist forests. The greatest contribution (60-70%, depending of the data source) to biomass burning emissions came from burned montane cloud forests (4.5 million Mg CO 2 over the study period), despite accounting for only 7.4-10% of the total burned area. Gross aboveground biomass emissions (7.55 ± 2.14 Tg CO 2 ; 0.43 ± 0.04 Tg CO; 24,012 ± 2,685 Mg CH 4 for the study area) were larger than previously reported for the Tropical Andes.

Print ISSN: 0886-6236

Electronic ISSN: 1944-9224

Topics: Biology , Chemistry and Pharmacology , Geography , Geosciences , Physics

Published by Wiley on behalf of American Geophysical Union (AGU).

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Forests, Vol. 9, Pages 305: Deforestation-Induced Fragmentation Increases Forest Fire Occurrence in Central Brazilian Amazonia (2018)

Celso H. L. Silva Junior; Luiz E. O. C. Aragão; Marisa G. Fonseca; Catherine T. Almeida; Laura B. Vedovato; Liana O. Anderson

MDPI Publishing

In: Forests

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Publication Date: 2018-06-02

Description: Forests, Vol. 9, Pages 305: Deforestation-Induced Fragmentation Increases Forest Fire Occurrence in Central Brazilian Amazonia Forests doi: 10.3390/f9060305 Authors: Celso H. L. Silva Junior Luiz E. O. C. Aragão Marisa G. Fonseca Catherine T. Almeida Laura B. Vedovato Liana O. Anderson Amazonia is home to more than half of the world&rsquo;s remaining tropical forests, playing a key role as reservoirs of carbon and biodiversity. However, whether at a slower or faster pace, continued deforestation causes forest fragmentation in this region. Thus, understanding the relationship between forest fragmentation and fire incidence and intensity in this region is critical. Here, we use MODIS Active Fire Product (MCD14ML, Collection 6) as a proxy of forest fire incidence and intensity (measured as Fire Radiative Power&mdash;FRP), and the Brazilian official Land-use and Land-cover Map to understand the relationship among deforestation, fragmentation, and forest fire on a deforestation frontier in the Brazilian Amazonia. Our results showed that forest fire incidence and intensity vary with levels of habitat loss and forest fragmentation. About 95% of active fires and the most intense ones (FRP &gt; 500 megawatts) were found in the first kilometre from the edges in forest areas. Changes made in 2012 in the Brazilian main law regulating the conservation of forests within private properties reduced the obligation to recover illegally deforested areas, thus allowing for the maintenance of fragmented areas in the Brazilian Amazonia. Our results reinforce the need to guarantee low levels of fragmentation in the Brazilian Amazonia in order to avoid the degradation of its forests by fire and the related carbon emissions.

Electronic ISSN: 1999-4907

Topics: Agriculture, Forestry, Horticulture, Fishery, Domestic Science, Nutrition

Published by MDPI Publishing

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Climatic and anthropogenic drivers of northern Amazon fires during the 2015/2016 El Niño event (2017)

Marisa G. Fonseca, Liana O. Anderson, Egidio Arai, Yosio E. Shimabukuro, Haron A. M. Xaud, Maristela R. Xaud, Nima Madani, Fabien H. Wagner, Luiz E. O. C. Aragão

Wiley

In: Ecological Applications

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Publication Date: 2017-09-19

Description: The strong El Niño Southern Oscillation (ENSO) event that occurred in 2015/2016 caused extreme drought in the northern Brazilian Amazon, especially in the state of Roraima, increasing fire occurrence. Here we map the extent of precipitation and fire anomalies and quantify the effects of climatic and anthropogenic drivers on fire occurrence during the 2015/2016 dry season (from December 2015 to March 2016) in the state of Roraima. To achieve these objectives we first estimated the spatial pattern of precipitation anomalies, based on long-term data from the TRMM (Tropical Rainfall Measuring Mission), and the fire anomaly, based on MODIS (Moderate Resolution Imaging Spectroradiometer) active fire detections during the referred period. Then, we integrated climatic and anthropogenic drivers in a Maximum Entropy (MaxEnt) model to quantify fire probability, assessing (i) the model accuracy during the 2015/2016 and the 2016/2017 dry seasons; (ii) the relative importance of each predictor variable on the model predictive performance; and (iii) the response curves, showing how each environmental variable affects the fire probability. Approximately 59% (132,900 km 2 ) of the study area was exposed to precipitation anomalies ≤ -1 standard deviation (SD) in January and ~48% (~106,800 km 2 ) in March. About 38% (86,200 km 2 ) of the study area experienced fire anomalies ≥ 1 SD in at least one month between December 2015 and March 2016. The distance to roads and the direct ENSO effect on fire occurrence were the two most influential variables on model predictive performance. Despite the improvement of governmental actions of fire prevention and firefighting in Roraima since the last intense ENSO event (1997/1998), we show that fire still gets out of control in the state during extreme drought events. Our results indicate that if no prevention actions are undertaken, future road-network expansion and a climate-induced increase in water stress will amplify fire occurrence in the northern Amazon, even in its humid dense forests. As an additional outcome of our analysis, we conclude that the model and the data we used may help to guide on-the-ground fire-prevention actions and firefighting planning and therefore minimize fire-related ecosystems degradation, economic losses and carbon emissions in Roraima. This article is protected by copyright. All rights reserved.

Print ISSN: 1051-0761

Electronic ISSN: 1939-5582

Topics: Biology

Published by Wiley on behalf of The Ecological Society of America (ESA).

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Water, Vol. 10, Pages 1220: Spatiotemporal Rainfall Trends in the Brazilian Legal Amazon between the Years 1998 and 2015 (2018)

Celso H. L. Silva Junior; Catherine T. Almeida; Jessflan R. N. Santos; Liana O. Anderson; Luiz E. O. C. Aragão; Fabrício B. Silva

MDPI Publishing

In: Water

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Publication Date: 2018-09-11

Description: Water, Vol. 10, Pages 1220: Spatiotemporal Rainfall Trends in the Brazilian Legal Amazon between the Years 1998 and 2015 Water doi: 10.3390/w10091220 Authors: Celso H. L. Silva Junior Catherine T. Almeida Jessflan R. N. Santos Liana O. Anderson Luiz E. O. C. Aragão Fabrício B. Silva Tropical forests play an important role as a reservoir of carbon and biodiversity, specifically forests in the Brazilian Amazon. However, the last decades have been marked by important changes in the Amazon, particularly those associated with climatic extremes. Quantifying the variability of rainfall patterns, hence, is essential for understanding changes and impacts of climate upon this ecosystem. The aim of this study was to analyse spatiotemporal trends in rainfall along the Brazilian Legal Amazon between 1998 and 2015. For this purpose, rainfall data derived from the Tropical Rainfall Measuring Mission satellite (TRMM) and nonparametric statistical methods, such as Mann&ndash;Kendall and Sen&rsquo;s Slope, were used. Through this approach, some patterns were identified. No evidence of significant rainfall trends (p &le; 0.05) for annual or monthly (except for September, which showed a significant negative trend) averages was found. However, significant monthly negative rainfall anomalies were found in 1998, 2005, 2010, and 2015, and positive in 1999, 2000, 2004, 2009, and 2013. The annual pixel-by-pixel analysis showed that 92.3% of the Brazilian Amazon had no rainfall trend during the period analysed, 4.2% had significant negative trends (p &le; 0.05), and another 3.5% had significant positive trends (p &le; 0.05). Despite no clear temporal rainfall trends for most of the Amazon had negative trends for September, corresponding to the peak of dry season in the majority of the region, and negative rainfall anomalies found in 22% of the years analysed, which indicate that water-dependent ecological processes may be negatively affected. Moreover, these processes may be under increased risk of disruption resulting from other drought-related events, such as wildfires, which are expect to be intensified by rainfall reduction during the Amazonian dry season.

Electronic ISSN: 2073-4441

Topics: Energy, Environment Protection, Nuclear Power Engineering

Published by MDPI Publishing

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