Forest‐Induced Exponential Growth of Precipitation Along Climatological Wind Streamlines Over the Amazon

Molina, Rubén D.; Salazar, Juan F.; Martínez, J. Alejandro; Villegas, Juan Camilo; Arias, Paola A.

doi:10.1029/2018jd029534

Cited by 60 publications

(46 citation statements)

References 55 publications

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“…The seasonal precipitation over large parts of the Amazon region is mainly characterized by wet conditions in the austral summer, associated with the active phase of the South American Monsoon System (Vera et al, 2006;Zhou & Lau, 1998) and a dry season in austral winter, in the absence of the South American Monsoon System forcing. Moreover, several studies have shown that the Amazon basin itself constitutes a major moisture source for the region, driven by the hydrologic regime of the rainforest (Builes-Jaramillo & Poveda, 2018;Drumond et al, 2014;Molina et al, 2019;Salati et al, 1979). In fact, the forest induces dry season rainfall, necessary to sustain itself when oceanic moisture supply is limited (Staal et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

The Forest Effects on the Isotopic Composition of Rainfall in the Northwestern Amazon Basin

et al. 2020

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In the Amazon basin, intense precipitation recycling across the forest significantly modifies the isotopic composition of rainfall (δ18O, δD). In the tropical hydrologic cycle, such an effect can be identified through deuterium excess (dxs), yet it remains unclear what environmental factors control dxs, increasing the uncertainty of dxs‐based paleoclimate reconstructions. Here we present a 4‐year record of the isotopic composition of rainfall, monitored in the northwestern Amazon basin. We analyze the isotopic variations as a function of the air mass history, based on atmospheric back trajectory analyses, satellite observations of precipitation upstream, leaf area index, and simulated moisture recycling along the transport pathway. We show that the precipitation recycling in the forest exerts a significant control on the isotopic composition of precipitation in the northwestern Amazon basin, especially on dxs during the dry season (r = 0.71). Applying these observations to existing speleothem and pollen paleorecords, we conclude that winter precipitation increased after the mid‐Holocene, as the expansion of the forest allowed for more moisture recycling. Therefore, forest effects should be considered when interpreting paleorecords of past precipitation changes.

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Section: Introductionmentioning

confidence: 99%

The Forest Effects on the Isotopic Composition of Rainfall in the Northwestern Amazon Basin

et al. 2020

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“…The southern Amazon is one of the most rapidly developing agricultural frontiers in the world, having experienced high rates of conversion of forest to croplands and pasturelands (Salazar et al, 2007;Instituto Nacional de Pesquisas Espaciais, 2014). Previous studies have demonstrated that these intense land use and land cover changes affect the regional precipitation (Lean et al, 1996;Costa and Foley, 2000;Davidson et al, 2012;Debortoli et al, 2015;Boers et al, 2017;Agudelo et al, 2019;Leite-Filho et al, 2019;Molina et al, 2019). These impacts are potentially important for the region, as some of its main economic activities, including agriculture, are highly dependent on climate (Sumila et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

The southern Amazon rainy season: The role of deforestation and its interactions with large‐scale mechanisms

Leite-Filho

Costa

2019

Intl Journal of Climatology

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Past studies presented evidence that deforestation may affect the precipitation seasonality in southern Amazon. This study uses daily rainfall data from Tropical Rainfall Measurement Mission 3B42 product and a recent yearly 1‐km land use dataset to evaluate the quantitative effects of deforestation on the onset, demise and length of the rainy season in southern Amazon for a period of 15 years (1998–2012). Additionally, we use the Niño4 index, zonal wind data and deforestation data to explain and predict the interannual variability of the onset of the rainy season. During this period, onset has delayed ~0.38 ± 0.05 days per year (5.7 ± 0.75 days in 15 years), demise has advanced 1.34 ± 0.76 days per year (20 ± 11.4 days in 15 years) and the rainy season has shortened by 1.81 ± 0.97 days per year (27 ± 14.5 days in 15 years). Onset, demise and length also present meridional and zonal gradients linked to large‐scale climate mechanisms. After removing the effects related to geographical position and year, we verified a relationship between onset, demise and length and deforestation: Onset delays ~0.4 ± 0.12 day, demise advances ~1.0 ± 0.22 day and length decreases ~0.9 ± 0.34 day per each 10% deforestation increase relative to existing forested area. We also present empirical evidence of the interaction between large‐scale and local‐scale processes, with interannual variation of the onset in the region explained by Niño4 sea surface temperature anomalies, Southern Hemisphere subtropical jet position, deforestation and their interactions (r2 = 69%, p < .001, mean absolute error = 2.7 days).

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“…A PEN-induced dieback in the Amazon could tip the rainforest from a sink of carbon to a possible source (Davidson et al, 2012). This could in turn amplify the magnitude of extreme hydrological and weather events that occur during El Niño, such as droughts, in a positive-feedback-like manner (Zemp et al, 2017;Salazar et al, 2018), as well as disrupt mechanisms of river flow regulation (Salazar et al, 2018;Mercado-Bettin et al, 2019) and continental precipitation distribution (Molina et al, 2019). Near-synchronous effects of this sort between different tipping elements could give rise to a "tipping cascade" that could contribute to a planetary-scale state shift (Lenton and Williams, 2013 forest collapse in most of the Amazon, our results also agree with Betts et al (2008) that some areas in western Amazonia (adjacent to the Andes) are less vulnerable and could act as a refuge for biodiversity.…”

Section: Discussionmentioning

confidence: 99%

Tipping the ENSO into a permanent El Niño can trigger state transitions in global terrestrial ecosystems

Duque-Villegas¹,

Salazar²,

Rendón³

2019

Preprint

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Abstract. Some large-scale components of the Earth's climate system have been identified as policy-relevant tipping elements, meaning that anthropogenic forcing and perturbations may push them across a tipping point threshold, with potential global scale impact on ecosystems and concomitant environmental and social phenomena. A pronounced change in the amplitude and/or frequency of the El Niño-Southern Oscillation (ENSO) is among such tipping elements. Here we use the Planet Simulator (PlaSim), an Earth system model of intermediate complexity, to investigate the potential impact on global climate and terrestrial ecosystems of shifting the current dynamics of the ENSO into a permanent El Niño. When forced with sea surface temperature (SST) derived from observations, the PlaSim model yields a realistic representation of large-scale climatological patterns, including realistic estimates of the global energy and water balances, and gross primary production. In a permanent El Niño state, we found significant differences in the global distribution of water and energy fluxes, and associated impacts on gross primary production, indicating that vegetation productivity decreases in the tropics whereas it increases in temperate and boreal regions. We identify regions in which these El Niño-induced changes are consistent with potential state transitions in global terrestrial ecosystems, including potential dieback of the Amazon rainforest, southward expansion of the Sahel, and further aridification of Australia.

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Forest‐Induced Exponential Growth of Precipitation Along Climatological Wind Streamlines Over the Amazon

Cited by 60 publications

References 55 publications

The Forest Effects on the Isotopic Composition of Rainfall in the Northwestern Amazon Basin

The Forest Effects on the Isotopic Composition of Rainfall in the Northwestern Amazon Basin

The southern Amazon rainy season: The role of deforestation and its interactions with large‐scale mechanisms

Tipping the ENSO into a permanent El Niño can trigger state transitions in global terrestrial ecosystems

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