Greenhouse Gas Induced Changes in the Seasonal Cycle of the Amazon Basin in Coupled Climate-Vegetation Regional Model

Justino, Flávio; Stordal, Frøde; Vizy, Edward K.; Cook, Kerry H.; Pereira, Marcos Paulo Santos

doi:10.3390/cli4010003

Cited by 8 publications

(13 citation statements)

References 34 publications

(60 reference statements)

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“…In all experiments, the CO 2 concentration was set to 325 ppm, which is based on boron isotopes in planktonic foraminifera shells for the MIS31 interval (Honisch et al, 2009). The MIS31 and CTR experiments have been described in further detail elsewhere by Justino et al (2017), but a brief discussion of the global climate differences between these two runs is provided below. Table 1 shows the global and hemispheric surface temperature values for the CTR and MIS31 simulations, and ERA-Interim (ERA-I; Dee et al, 2011) and HadCRUT4 for the 1980-2010 interval.…”

Section: Datasetmentioning

confidence: 99%

“…The Marine Isotope Stage 31 (MIS31; early Pleistocene 1085-1055 ka) is a key paleoclimate period to simulate and analyze the global environmental response to a significantly modified climate forcing (Lisiecki and Raymo, 2005;Yin and Berger, 2012). This interval was characterized by boreal summer temperatures that were several degrees greater than modern climate (up to 6 • C), with a substantial recession of the Northern Hemisphere (NH) sea ice (Melles et al, 2012;Justino et al, 2017). On long timescales, Earth's climate is primarily controlled by external and internal processes related to the astronomical forcing and the atmospheric concentration of greenhouse gases (IPCC, 2013;Erb et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…Significantly modified periodicity and amplitude of past ENSO regimes, and their global influence, shed light on the potential effect of human-induced climate change on the equatorial Pacific, and consequently on future ENSO-like climate. Furthermore, it should be argued that disagreement in the magnitude of cooling or warming among coupled climate models and paleoreconstructions may be related to the local responses of temperature and precipitation elicited by distinct ENSO in both spatial and temporal variability (Peltier and Solheim, 2004;Jost et al, 2005;Yin and Berger, 2012;Dolan et al, 2015;Justino et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…The ocean component has 31 vertical levels with layer thicknesses ranging from 10 m at the surface to 500 m at the ocean bottom (16 levels in the upper 200 m). Additional details on the ICTP-CGCM coupled model are discussed by Justino et al (2017). Farneti et al (2014) used the ICTP-CGCM to examine the interaction between the tropical and subtropical northern Pacific at decadal timescales, suggesting that extratropical atmospheric responses to tropical forcing feed back onto the ocean dynamics leading to a time-delayed response of the tropical oceans.…”

Section: Introductionmentioning

confidence: 99%

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A modified seasonal cycle during MIS31 super-interglacial favors stronger interannual ENSO and monsoon variability

et al. 2019

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It has long been recognized that the amplitude of the seasonal cycle can substantially modify climate features in distinct timescales. This study evaluates the impact of the enhanced seasonality characteristic of the Marine Isotope Stage 31 (MIS31) on the El Niño-Southern Oscillation (ENSO). Based upon coupled climate simulations driven by present-day (CTR) and MIS31 boundary conditions, we demonstrate that the CTR simulation shows a significant concentration of power in the 3-7-year band and on the multidecadal timescale between 15 and 30 years. However, the MIS31 simulation shows drastically modified temporal variability of the ENSO, with stronger power spectrum at interannual timescales but the absence of decadal periodicity. Increased meridional gradient of sea surface temperature (SST) and wind stress in the Northern Hemisphere subtropics are revealed to be the primary candidates responsible for changes in the equatorial variability. The oceanic response to the MIS31 ENSO extends to the extratropics, and fits nicely with SST anomalies delivered by paleoreconstructions. The implementation of the MIS31 conditions results in a distinct global monsoon system and its link to the ENSO in respect to current conditions. In particular, the Indian monsoon intensified but no correlation with ENSO is found in the MIS31 climate, diverging from conditions delivered by our current climate in which this monsoon is significantly correlated with the NIÑO34 index. This indicates that monsoonal precipitation for this interglacial is more closely connected to hemispherical features than to the tropical-extratropical climate interaction.

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Section: Datasetmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A modified seasonal cycle during MIS31 super-interglacial favors stronger interannual ENSO and monsoon variability

et al. 2019

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“…The response of South American vegetation to climate change may be particularly important, since this continent still contains the largest (but rapidly diminishing) continuous area of tropical rainforest [3]. There are several models that simulate the dynamic relationship between climate and vegetation at a macrogeographic scale [4][5][6][7][8][9]. These could be of great utility for climate modelers since, unlike many climate simulations, they consider the atmosphere and terrestrial biosphere as a coupled system with biogeophysical and biogeochemical processes occurring across a range of timescales [10].…”

Section: Introductionmentioning

confidence: 99%

Response of South American Terrestrial Ecosystems to Future Patterns of Sea Surface Temperature

Pereira¹,

Costa²,

Justino³

et al. 2017

Advances in Meteorology

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Global warming in the first half of the 21st century is likely to have profound influences on South American vegetation and climate. Although coupled atmosphere-biosphere models have been widely used to forecast future vegetation patterns under various scenarios of global warming, they have not been used to assess the potentially critical role of variations in sea surface temperature (SST) in modifying the climate-vegetation interactions. Here, we use monthly output of a 100-year coupled model run to investigate the relationship between SST, precipitation, and productivity of vegetation. Specifically, we assess statistical correlations between SST variability and vegetation in six different South America regions: Northern South America, Western Amazonia, Eastern Amazonia, Northeast Brazil, Central Brazil, and Patagonia. Our model robustly simulates changes in mean precipitation, net primary production (NPP), upper canopy leaf area index (LAI), and lower canopy LAI under warming and nonwarming scenarios. Most significantly, we demonstrate that spatial-temporal variability in SST exerts a strong influence over the vegetation dynamics in all six South American regions.

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Climate Change and Models

Majumder

Saha

2016

Impact of Climate Change on Hydro-Energy Potential

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Greenhouse Gas Induced Changes in the Seasonal Cycle of the Amazon Basin in Coupled Climate-Vegetation Regional Model

Cited by 8 publications

References 34 publications

A modified seasonal cycle during MIS31 super-interglacial favors stronger interannual ENSO and monsoon variability

A modified seasonal cycle during MIS31 super-interglacial favors stronger interannual ENSO and monsoon variability

Response of South American Terrestrial Ecosystems to Future Patterns of Sea Surface Temperature

Climate Change and Models

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