The Drought of Amazonia in 2005

Marengo, José A.; Nobre, Carlos A.; Tomasella, Javier; Oyama, Marcos Daisuke; Sampaio, Gilvan; Oliveira, Rafael de; Camargo, Hélio; Alves, Lincoln M.; Brown, I. Foster

doi:10.1175/2007jcli1600.1

Cited by 637 publications

(607 citation statements)

References 30 publications

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“…Likewise, anomalously warm conditions in the southern tropical Atlantic tend to delay the northward migration of the ITCZ and generate wetter-than-normal conditions in the northern Nordeste. These precipitation anomalies can occur on a variety of timescales including intra-annual (e.g., Marengo et al, 2008 andLewis, et al, 2010), decadal (e.g., Hastenrath andHeller, 1977 andShukla, 1996), and, perhaps, centennial/millennial (e.g., Cruz et al, 2009 and this paper). Thus, we posit that the centennial-millennial detrital-rich intervals represented by the Ti/Ca peaks were produced by centennial-millennial increases of regional rainfall that coincided with a cooler northern tropical Atlantic, warmer southern tropical Atlantic, and an anomalously southward-displaced mean position of the ITCZ.…”

Section: Periods Of Anomalous Warmth In the Northern Tropical Atlantimentioning

confidence: 76%

The role of North Brazil Current transport in the paleoclimate of the Brazilian Nordeste margin and paleoceanography of the western tropical Atlantic during the late Quaternary

Nace

Baker

Dwyer

et al. 2014

Palaeogeography, Palaeoclimatology, Palaeoecology

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Section: Periods Of Anomalous Warmth In the Northern Tropical Atlantimentioning

confidence: 76%

The role of North Brazil Current transport in the paleoclimate of the Brazilian Nordeste margin and paleoceanography of the western tropical Atlantic during the late Quaternary

Nace

Baker

Dwyer

et al. 2014

Palaeogeography, Palaeoclimatology, Palaeoecology

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“…[11] The elevated mortality observed in the Central Amazon in 2005 is unlikely to be related to the 2005Ama-zon drought since analysis of both rainfall and river discharge data showed that this drought had little effect on Central or Eastern Amazonia [Marengo et al, 2008]. In Manaus, the effects of rainfall anomalies were observed late in the dry season (September-October) [Marengo et al, 2008], whereas the elevated mortality reported here from both Landsat images and forest plot data occurred before the late dry season.…”

Section: Resultsmentioning

confidence: 99%

“…In 2005 the Amazon basin experienced one of the most severe droughts of the past 100 years [Marengo et al, 2008] and analyses of forest plot data suggest that the drought produced elevated tree mortality across the entire Amazon basin [Phillips et al, 2009]. Yet, the 2005 drought most strongly affected western and southwestern Amazonia [Marengo et al, 2008] which raises a question as to whether the tree elevated mortality observed across the basin was the result of drought alone. Here we present an approach linking field-measured tree mortality data, remote sensing analyses, and an empirical model to quantify widespread tree mortality across the Amazon produced by a single squall line observed from January 16 to January 18, 2005.…”

Section: Introductionmentioning

confidence: 99%

Widespread Amazon forest tree mortality from a single cross‐basin squall line event

Negrón‐Juárez

Chambers²,

Guimarães

et al. 2010

Geophysical Research Letters

127

119

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Climate change is expected to increase the intensity of extreme precipitation events in Amazonia that in turn might produce more forest blowdowns associated with convective storms. Yet quantitative tree mortality associated with convective storms has never been reported across Amazonia, representing an important additional source of carbon to the atmosphere. Here we demonstrate that a single squall line (aligned cluster of convective storm cells) propagating across Amazonia in January, 2005, caused widespread forest tree mortality and may have contributed to the elevated mortality observed that year. Forest plot data demonstrated that the same year represented the second highest mortality rate over a 15‐year annual monitoring interval. Over the Manaus region, disturbed forest patches generated by the squall followed a power‐law distribution (scaling exponent α = 1.48) and produced a mortality of 0.3–0.5 million trees, equivalent to 30% of the observed annual deforestation reported in 2005 over the same area. Basin‐wide, potential tree mortality from this one event was estimated at 542 ± 121 million trees, equivalent to 23% of the mean annual biomass accumulation estimated for these forests. Our results highlight the vulnerability of Amazon trees to wind‐driven mortality associated with convective storms. Storm intensity is expected to increase with a warming climate, which would result in additional tree mortality and carbon release to the atmosphere, with the potential to further warm the climate system.

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“…In contrast, in 2009, the Amazon basin was affected by extraordinarily strong rainfalls, which raised the water level of its rivers to a magnitude and duration rarely observed in the region, again causing economic and social damage to the human populations residing there (Marengo et al, 2011a(Marengo et al, , 2012. Extreme climatic events such as these are worrying in the Amazon region not only because they reach riverine populations, but also because they cause a loss of biodiversity (for example, millions of fish died in the 2005 drought in the region).…”

Section: Introductionmentioning

confidence: 99%

Possible impacts of climate change on wetlands and its biota in the Brazilian Amazon

Barros

Albernaz

2014

Braz. J. Biol.

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Wetlands cover approximately 6% of the Earth´s surface. They are frequently found at the interface between terrestrial and aquatic ecosystems and are strongly dependent on the water cycle. For this reason, wetlands are extremely vulnerable to the effects of climate change. Mangroves and floodplain ecosystems are some of the most important environments for the Amazonian population, as a source of proteins and income, and are thus the types of wetlands chosen for this review. Some of the main consequences that can be predicted from climate change for wetlands are modifications in hydrological regimes, which can cause intense droughts or inundations. A possible reduction in rainfall can cause a decrease of the areas of mangroves and floodplains, with a consequent decline in their species numbers. Conversely, an increase in rainfall would probably cause the substitution of plant species, which would not be able to survive under new conditions for a long period. An elevation in water temperature on the floodplains would cause an increase in frequency and duration of hypoxic or anoxic episodes, which might further lead to a reduction in growth rates or the reproductive success of many species. In mangroves, an increase in water temperature would influence the sea level, causing losses of these environments through coastal erosion processes. Therefore, climate change will likely cause the loss of, or reduction in, Amazonian wetlands and will challenge the adaptability of species, composition and distribution, which will probably have consequences for the human population that depend on them.Keywords: global warming, wetlands, mangrove, floodplains, Amazonia. Possíveis impactos das mudanças climáticas em áreas úmidase sua biota na Amazônia brasileira ResumoAs áreas úmidas cobrem aproximadamente 6% da superfície da terra e são frequentemente encontradas na interface entre ecossistemas terrestres e aquáticos e fortemente dependentes do ciclo da água. Por esta razão são extremamente vulneráveis aos efeitos das alterações do clima. Os ecossistemas de manguezais e várzeas são muito importantes para os seres humanos da Amazônia, porque são de onde eles extraem algumas das principais fontes de proteínas e renda, e, por isso, foram os dois tipos de áreas úmidas escolhidos para esse estudo. Entre as principais consequências das mudanças climáticas previstas para esses ambientes estão as alterações nos regimes hidrológicos, que podem causar grandes secas ou inundações. A possível redução das chuvas pode causar a diminuição das áreas de mangue e várzea, provocando um rápido declínio de suas espécies. Por outro lado, o aumento das chuvas teria como provável consequência a substituição de espécies de plantas, que não seriam capazes de sobreviver sob as novas condições por um longo período de tempo. As principais consequências do aumento da temperatura da água entre as áreas úmidas seria que nas várzeas este parâmetro aumentaria a frequência ou duração dos episódios hipóxicos e/ou anóxicos, podendo causar a redução da taxa de...

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The Drought of Amazonia in 2005

Cited by 637 publications

References 30 publications

The role of North Brazil Current transport in the paleoclimate of the Brazilian Nordeste margin and paleoceanography of the western tropical Atlantic during the late Quaternary

The role of North Brazil Current transport in the paleoclimate of the Brazilian Nordeste margin and paleoceanography of the western tropical Atlantic during the late Quaternary

Widespread Amazon forest tree mortality from a single cross‐basin squall line event

Possible impacts of climate change on wetlands and its biota in the Brazilian Amazon

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