Your search keyword '"El niño-Southern Oscillation"' showing total 81 results

1. Cross‐scale assessments of the impacts and resilience of subtropical montane cloud forests to chronic seasonal droughts and episodic typhoons.

Author

Wang, Hsueh‐Ching and Huang, Cho‐ying

Subjects

*TYPHOONS, *MOUNTAIN forests, *CLOUD forests, *DROUGHTS, *SEASONS, *EXTREME weather

Abstract

Montane cloud forests (MCFs) are ecosystems frequently immersed in fog and are vital for the terrestrial hydrological cycle and biodiversity hotspots. However, the potential impacts of climate change, particularly intensified droughts and typhoons, on the persistence of ecosystems remain unclear. Our study conducted cross‐scale assessments using 6‐year (2016–2021) ground litterfall and 21‐year (2001–2021) satellite greenness data (the Enhanced Vegetation Index [EVI] and the EVI anomaly change [ΔEVI%]), gross primary productivity anomaly change (ΔGPP%), and meteorological variables (the standardized precipitation index [SPI] and wind speed). We found a positive correlation between summer EVI and ΔGPP% with the SPI‐3 (3‐month time scale), while winter litterfall showed a negative correlation. Maximum typhoon daily wind speed was negatively correlated with summer and the monthly ΔEVI% and ΔGPP%. These findings suggest vegetation damage and productivity loss were related to drought and typhoon intensities. Furthermore, our analysis highlighted that chronic seasonal droughts had more pronounced impacts on MCFs than severe typhoons, implying that high precipitation and frequent fog immersion do not necessarily mitigate the ramifications of water deficit on MCFs but might render MCFs more sensitive and vulnerable to drought. A significant negative correlation between the summer and winter ΔEVI% and ΔGPP% of the same year, suggesting disturbance severity during summer may facilitate vegetation regrowth and carbon accumulation in the subsequent winter. This finding may be attributed to the ecological resilience of MCFs, which enables them to recover from the previous summer. In the long‐term, our results indicated an increase in vegetation resilience over two decades in MCFs, likely driven by rising temperatures and elevated carbon dioxide levels. However, the enhancement of resilience might be overshadowed by the potential intensified droughts and typhoons in the future, potentially causing severe damage and insufficient recovery times for MCFs, thus raising concerns about uncertainties regarding their sustained resilience. [ABSTRACT FROM AUTHOR]

Published

2024

2. Climate-mediated changes in marine ecosystem regulation during El Niño.

Author

Lindegren, Martin, Checkley, David M, Koslow, Julian A, Goericke, Ralf, and Ohman, Mark D

Subjects

Animals, Fishes, Ecosystem, California, Climate Change, El Nino-Southern Oscillation, El Niño, Pacific Decadal Oscillation, bottom-up, climate, ecosystem regulation, food web model, management, top-down, El Nino, Climate Action, Life Below Water, Environmental Sciences, Biological Sciences, Ecology

Abstract

The degree to which ecosystems are regulated through bottom-up, top-down, or direct physical processes represents a long-standing issue in ecology, with important consequences for resource management and conservation. In marine ecosystems, the role of bottom-up and top-down forcing has been shown to vary over spatio-temporal scales, often linked to highly variable and heterogeneously distributed environmental conditions. Ecosystem dynamics in the Northeast Pacific have been suggested to be predominately bottom-up regulated. However, it remains unknown to what extent top-down regulation occurs, or whether the relative importance of bottom-up and top-down forcing may shift in response to climate change. In this study, we investigate the effects and relative importance of bottom-up, top-down, and physical forcing during changing climate conditions on ecosystem regulation in the Southern California Current System (SCCS) using a generalized food web model. This statistical approach is based on nonlinear threshold models and a long-term data set (~60 years) covering multiple trophic levels from phytoplankton to predatory fish. We found bottom-up control to be the primary mode of ecosystem regulation. However, our results also demonstrate an alternative mode of regulation represented by interacting bottom-up and top-down forcing, analogous to wasp-waist dynamics, but occurring across multiple trophic levels and only during periods of reduced bottom-up forcing (i.e., weak upwelling, low nutrient concentrations, and primary production). The shifts in ecosystem regulation are caused by changes in ocean-atmosphere forcing and triggered by highly variable climate conditions associated with El Niño. Furthermore, we show that biota respond differently to major El Niño events during positive or negative phases of the Pacific Decadal Oscillation (PDO), as well as highlight potential concerns for marine and fisheries management by demonstrating increased sensitivity of pelagic fish to exploitation during El Niño.

Published

2018

3. Plant hydraulics, stomatal control, and the response of a tropical forest to water stress over multiple temporal scales

Author

Matteo Detto and Stephen W. Pacala

Subjects

El Nino-Southern Oscillation, Plant Leaves, Soil, Global and Planetary Change, Dehydration, Ecology, Environmental Chemistry, Forests, Plants, Ecosystem, Droughts, Trees, General Environmental Science

Abstract

Many tropical regions are experiencing an intensification of drought, with increasing severity and frequency. The ecosystem response to these changes is still highly uncertain. On short time scales (from diurnal to seasonal), tropical forests respond to water stress by physiological controls, such as stomatal regulation and phenological adjustment, to cope with increasing atmospheric water demand and reduced water supply. However, the interactions among biological processes and co-varying environmental factors that determine the ecosystem-level fluxes are still unclear. Furthermore, climate variability at longer time scales, such as that generated by ENSO, produces less predictable effects because it depends on a highly stochastic combination of factors that might vary among forests and even between events in the same forest. This study will present some emerging patterns of response to water stress from 5 years of water, carbon, and energy fluxes observed on a seasonal tropical forest in central Panama, including an increase in productivity during the 2015 El Niño. These responses depend on the combination of environmental factors experienced by the forest throughout the seasonal cycle, in particular, increase in solar radiation, stimulating productivity, and increasing vapor pressure deficit (VPD) and decreasing soil moisture, limiting stomata opening. These results suggest a critical role of plant hydraulics in mediating the response to water stress over a broad range of temporal scales (diurnal, intraseasonal, seasonal, and interannual), by acclimating canopy conductance to light and VPD during different soil moisture regimes. A multilayer photosynthesis model coupled with a plant hydraulics scheme can reproduce these complex responses. However, results depend critically on parameters regulating water transport efficiency and the cost of water stress. As these costs have not been properly identified and quantified yet, more empirical research is needed to elucidate physiological mechanisms of hydraulic failure and recover, for example embolism repair and xylem regrowth.

Published

2022

4. A boundary current drives synchronous growth of marine fishes across tropical and temperate latitudes.

Author

Ong, Joyce J. L., Rountrey, Adam N., Black, Bryan A., Nguyen, Hoang Minh, Coulson, Peter G., Newman, Stephen J., Wakefield, Corey B., Meeuwig, Jessica J., and Meekan, Mark G.

Subjects

*CLIMATE change, *TEMPERATE climate, *FISH habitats, *LATITUDE, *SPECIES diversity, MARINE fish growth

Abstract

Abstract: Entrainment of growth patterns of multiple species to single climatic drivers can lower ecosystem resilience and increase the risk of species extinction during stressful climatic events. However, predictions of the effects of climate change on the productivity and dynamics of marine fishes are hampered by a lack of historical data on growth patterns. We use otolith biochronologies to show that the strength of a boundary current, modulated by the El Niño‐Southern Oscillation, accounted for almost half of the shared variance in annual growth patterns of five of six species of tropical and temperate marine fishes across 23° of latitude (3000 km) in Western Australia. Stronger flow during La Niña years drove increased growth of five species, whereas weaker flow during El Niño years reduced growth. Our work is the first to link the growth patterns of multiple fishes with a single oceanographic/climate phenomenon at large spatial scales and across multiple climate zones, habitat types, trophic levels and depth ranges. Extreme La Niña and El Niño events are predicted to occur more frequently in the future and these are likely to have implications for these vulnerable ecosystems, such as a limited capacity of the marine taxa to recover from stressful climatic events. [ABSTRACT FROM AUTHOR]

Published

2018

5. Amazon drought and forest response: Largely reduced forest photosynthesis but slightly increased canopy greenness during the extreme drought of 2015/2016.

Author

Yang, Jia, Tian, Hanqin, Pan, Shufen, Chen, Guangsheng, Zhang, Bowen, and Dangal, Shree

Subjects

*FOREST ecology, *EFFECT of drought on plants, *PHOTOSYNTHESIS, *FOREST canopies, *CARBON dioxide, *CHLOROPHYLL spectra, *VEGETATION greenness

Abstract

Abstract: Amazon droughts have impacted regional ecosystem functioning as well as global carbon cycling. The severe dry‐season droughts in 2005 and 2010, driven by Atlantic sea surface temperature (SST) anomaly, have been widely investigated in terms of drought severity and impacts on ecosystems. Although the influence of Pacific SST anomaly on wet‐season precipitation has been well recognized, it remains uncertain to what extent the droughts driven by Pacific SST anomaly could affect forest greenness and photosynthesis in the Amazon. Here, we examined the monthly and annual dynamics of forest greenness and photosynthetic capacity when Amazon ecosystems experienced an extreme drought in 2015/2016 driven by a strong El Niño event. We found that the drought during August 2015–July 2016 was one of the two most severe meteorological droughts since 1901. Due to the enhanced solar radiation during this drought, overall forest greenness showed a small increase, and 21.6% of forests even greened up (greenness index anomaly ≥1 standard deviation). In contrast, solar‐induced chlorophyll fluorescence (SIF), an indicator of vegetation photosynthetic capacity, showed a significant decrease. Responses of forest greenness and photosynthesis decoupled during this drought, indicating that forest photosynthesis could still be suppressed regardless of the variation in canopy greenness. If future El Niño frequency increases as projected by earth system models, droughts would result in persistent reduction in Amazon forest productivity, substantial changes in tree composition, and considerable carbon emissions from Amazon. [ABSTRACT FROM AUTHOR]

Published

2018

6. Increased mortality of tropical tree seedlings during the extreme 2015–16 El Niño

Author

S. Joseph Wright, Owen T. Lewis, Bettina M. J. Engelbrecht, Lars Markesteijn, F. Andrew Jones, Eric Manzané-Pinzón, Liza S. Comita, and Luke Browne

Subjects

El Nino-Southern Oscillation, Tropical Climate, Global and Planetary Change, Ecology, Forest dynamics, biology, Global warming, food and beverages, Climate change, Tropics, Plant community, Understory, Forests, biology.organism_classification, Droughts, Trees, Geography, Seedlings, Seedling, Environmental Chemistry, Seasons, Tropical and subtropical moist broadleaf forests, General Environmental Science

Abstract

As extreme climate events are predicted to become more frequent because of global climate change, understanding their impacts on natural systems is crucial. Tropical forests are vulnerable to droughts associated with extreme El Niño events. However, little is known about how tropical seedling communities respond to El Niño-related droughts, even though patterns of seedling survival shape future forest structure and diversity. Using long-term data from eight tropical moist forests spanning a rainfall gradient in central Panama, we show that community-wide seedling mortality increased by 11% during the extreme 2015-16 El Niño, with mortality increasing most in drought-sensitive species and in wetter forests. These results indicate that severe El Niño-related droughts influence understory dynamics in tropical forests, with effects varying both within and across sites. Our findings suggest that predicted increases in the frequency of extreme El Niño events will alter tropical plant communities through their effects on early life stages.

Published

2021

7. Unusual characteristics of the carbon cycle during the 2015−2016 El Niño

Author

Ana Bastos, Kai Wang, Stephen W. Pacala, Hao Xu, Shilong Piao, Philippe Ciais, Jiafu Mao, Ralph F. Keeling, Xiaoying Shi, Frédéric Chevallier, Anping Chen, Chris Huntingford, Xuhui Wang, Sino-French Institute for Earth System Science, College of Urban and Environmental Sciences, Peking University [Beijing], Laboratoire des Sciences du Climat et de l'Environnement [Gif-sur-Yvette] (LSCE), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Environmental Sciences Division [Oak Ridge], Oak Ridge National Laboratory [Oak Ridge] (ORNL), UT-Battelle, LLC-UT-Battelle, LLC, Centre for Ecology and Hydrology [Wallingford] (CEH), Natural Environment Research Council (NERC), Department of Biogeochemical Integration [Jena], Max Planck Institute for Biogeochemistry (MPI-BGC), Max-Planck-Gesellschaft-Max-Planck-Gesellschaft, Scripps Institution of Oceanography (SIO - UC San Diego), University of California [San Diego] (UC San Diego), University of California (UC)-University of California (UC), Department of Ecology and Evolutionary Biology [Princeton], Princeton University, Colorado State University [Fort Collins] (CSU), U.S. Department of Energy, USDOE: DE‐AC05‐00OR22725, Office of Science, SC, Biological and Environmental Research, BER, National Natural Science Foundation of China, NSFC: 41861134036, 41988101, We thank Dr. Pieter Tans and Dr. Ed Dlugokencky for providing the CO mole fraction data. We also thank the TRENDYv6 modelers for their simulations and Dr. Christian Rödenbeck for the Jena CarboScope inversion datasets. This study was supported by the National Natural Science Foundation of China (grant nos. 41861134036 and 41988101) and an Oak Ridge National Lab subcontract (grant no. 4000167205). J. Mao and X. Shi were supported by the Reducing Uncertainties in Biogeochemical Interactions through Synthesis and Computation Science Focus Area and the Terrestrial Ecosystem Science Scientific Focus Area project in the Earth and Environmental Systems Sciences Division of the Biological and Environmental Research (BER) office in the US Department of Energy Office of Science. Oak Ridge National Laboratory is supported by the Office of Science of the US Department of Energy under contract no. DE‐AC05‐00OR22725. 2, Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ), Scripps Institution of Oceanography (SIO), and University of California-University of California

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, [SDE.MCG]Environmental Sciences/Global Changes, chemistry.chemical_element, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Ecology and Environment, Carbon Cycle, Carbon cycle, atmospheric CO2 growth rate (CGR), Meteorology and Climatology, medicine, Environmental Chemistry, Ecosystem, El Niño, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, Ecology, Atmosphere, Anomaly (natural sciences), Northern Hemisphere, Carbon Dioxide, 15. Life on land, Seasonality, medicine.disease, Carbon, northern terrestrial ecosystems, Productivity (ecology), chemistry, 13. Climate action, CO2 seasonal-cycle amplitude (SCA), soil water deficit, Environmental science, Terrestrial ecosystem, net biome productivity (NBP)

Abstract

International audience; The 2015−2016 El Niño was one of the strongest on record, but its influence on the carbon balance is less clear. Using Northern Hemisphere atmospheric CO2 observations, we found both detrended atmospheric CO2 growth rate (CGR) and CO2 seasonal-cycle amplitude (SCA) of 2015−2016 were much higher than that of other El Niño events. The simultaneous high CGR and SCA were unusual, because our analysis of long-term CO2 observations at Mauna Loa revealed a significantly negative correlation between CGR and SCA. Atmospheric inversions and terrestrial ecosystem models indicate strong northern land carbon uptake during spring but substantially reduced carbon uptake (or high emissions) during early autumn, which amplified SCA but also resulted in a small anomaly in annual carbon uptake of northern ecosystems in 2015−2016. This negative ecosystem carbon uptake anomaly in early autumn was primarily due to soil water deficits and more litter decomposition caused by enhanced spring productivity. Our study demonstrates a decoupling between seasonality and annual carbon cycle balance in northern ecosystems over 2015−2016, which is unprecedented in the past five decades of El Niño events.

Published

2021

8. Multi-century tree-ring precipitation record reveals increasing frequency of extreme dry events in the upper Blue Nile River catchment.

Author

Mokria, Mulugeta, Gebrekirstos, Aster, Abiyu, Abrham, Van Noordwijk, Meine, and Bräuning, Achim

Subjects

*CLIMATE change, *RAINFALL, *TREE-rings, *DENDROCLIMATOLOGY

Abstract

Climate-related environmental and humanitarian crisis are important challenges in the Great Horn of Africa ( GHA). In the absence of long-term past climate records in the region, tree-rings are valuable climate proxies, reflecting past climate variations and complementing climate records prior to the instrumental era. We established annually resolved multi-century tree-ring chronology from Juniperus procera trees in northern Ethiopia, the longest series yet for the GHA. The chronology correlates significantly with wet-season ( r = .64, p < .01) and annual ( r = .68, p < .01) regional rainfall. Reconstructed rainfall since A.D. 1811 revealed significant interannual variations between 2.2 and 3.8 year periodicity, with significant decadal and multidecadal variations during 1855-1900 and 1960-1990. The duration of negative and positive rainfall anomalies varied between 1-7 years and 1-8 years. Approximately 78.4% (95%) of reconstructed dry (extreme dry) and 85.4% (95%) of wet (extreme wet) events lasted for 1 year only and corresponded to historical records of famine and flooding, suggesting that future climate change studies should be both trend and extreme event focused. The average return periods for dry (extreme dry) and wet (extreme wet) events were 4.1 (8.8) years and 4.1 (9.5) years. Extreme-dry conditions during the 19th century were concurrent with drought episodes in equatorial eastern Africa that occurred at the end of the Little Ice Age. El Niño and La Niña events matched with 38.5% and 50% of extreme-dry and extreme-wet events. Equivalent matches for positive and negative Indian Ocean Dipole events were weaker, reaching 23.1 and 25%, respectively. Spatial correlations revealed that reconstructed rainfall represents wet-season rainfall variations over northern Ethiopia and large parts of the Sahel belt. The data presented are useful for backcasting climate and hydrological models and for developing regional strategic plans to manage scarce and contested water resources. Historical perspectives on long-term regional rainfall variability improve the interpretation of recent climate trends. [ABSTRACT FROM AUTHOR]

Published

2017

9. Interannual variation in methane emissions from tropical wetlands triggered by repeated El Niño Southern Oscillation.

Author

Zhu, Qiuan, Peng, Changhui, Ciais, Philippe, Jiang, Hong, Liu, Jinxun, Bousquet, Philippe, Li, Shiqin, Chang, Jie, Fang, Xiuqin, Zhou, Xiaolu, Chen, Huai, Liu, Shirong, Lin, Guanghui, Gong, Peng, Wang, Meng, Wang, Han, Xiang, Wenhua, and Chen, Jing

Subjects

*ATMOSPHERIC methane, *SOUTHERN oscillation, *EMISSIONS (Air pollution), *WETLANDS, EL Nino

Abstract

Methane (CH4) emissions from tropical wetlands contribute 60%-80% of global natural wetland CH4 emissions. Decreased wetland CH4 emissions can act as a negative feedback mechanism for future climate warming and vice versa. The impact of the El Niño-Southern Oscillation (ENSO) on CH4 emissions from wetlands remains poorly quantified at both regional and global scales, and El Niño events are expected to become more severe based on climate models' projections. We use a process-based model of global wetland CH4 emissions to investigate the impacts of the ENSO on CH4 emissions in tropical wetlands for the period from 1950 to 2012. The results show that CH4 emissions from tropical wetlands respond strongly to repeated ENSO events, with negative anomalies occurring during El Niño periods and with positive anomalies occurring during La Niña periods. An approximately 8-month time lag was detected between tropical wetland CH4 emissions and ENSO events, which was caused by the combined time lag effects of ENSO events on precipitation and temperature over tropical wetlands. The ENSO can explain 49% of interannual variations for tropical wetland CH4 emissions. Furthermore, relative to neutral years, changes in temperature have much stronger effects on tropical wetland CH4 emissions than the changes in precipitation during ENSO periods. The occurrence of several El Niño events contributed to a lower decadal mean growth rate in atmospheric CH4 concentrations throughout the 1980s and 1990s and to stable atmospheric CH4 concentrations from 1999 to 2006, resulting in negative feedback to global warming. [ABSTRACT FROM AUTHOR]

Published

2017

10. Human disturbance amplifies Amazonian El Niño-Southern Oscillation signal.

Author

Bush, Mark B., Correa‐Metrio, Alexander, Woesik, Robert, Shadik, Courtney R., and McMichael, Crystal N. H.

Subjects

*CLIMATE change, *SEDIMENTARY basins, *SEDIMENTS, *GLOBAL warming, EL Nino

Abstract

The long-term interaction between human activity and climate is subject to increasing scrutiny. Humans homogenize landscapes through deforestation, agriculture, and burning and thereby might reduce the capacity of landscapes to provide archives of climate change. Alternatively, land-use change might overwhelm natural buffering and amplify latent climate signals, rendering them detectable. Here we examine a sub-annually resolved sedimentary record from Lake Sauce in the western Amazonian lowlands that spans 6900 years. Finely-laminated sediments were deposited from ca. 5000 years ago until the present, and human activity in the watershed was revealed through the presence of charcoal and maize agriculture. The laminations, analyzed for color content and bandwidth, showed distinctive changes that were coupled to more frequent occurrence of fossil maize pollen. As agricultural activity intensified ca. 2200 cal. BP, the 2- to 8-year periodicity characteristic of El Niño-Southern Oscillation became evident in the record. These agricultural activities appeared to have amplified an existing, but subtle climatic signal that was previously absorbed by natural vegetation. When agricultural activity slowed, or land use around Lake Sauce changed at ca. 800 cal. BP, the signal of El Niño-Southern Oscillation ( ENSO) activity became erratic. [ABSTRACT FROM AUTHOR]

Published

2017

11. Global vegetation productivity response to climatic oscillations during the satellite era.

Author

Gonsamo, Alemu, Chen, Jing M., and Lombardozzi, Danica

Subjects

*VEGETATION & climate, *ENVIRONMENTAL engineering, *GLOBAL warming, *CLIMATE change, *SOUTHERN oscillation

Abstract

Climate control on global vegetation productivity patterns has intensified in response to recent global warming. Yet, the contributions of the leading internal climatic variations to global vegetation productivity are poorly understood. Here, we use 30 years of global satellite observations to study climatic variations controls on continental and global vegetation productivity patterns. El Niño-Southern Oscillation ( ENSO) phases (La Niña, neutral, and El Niño years) appear to be a weaker control on global-scale vegetation productivity than previously thought, although continental-scale responses are substantial. There is also clear evidence that other non- ENSO climatic variations have a strong control on spatial patterns of vegetation productivity mainly through their influence on temperature. Among the eight leading internal climatic variations, the East Atlantic/West Russia Pattern extensively controls the ensuing year vegetation productivity of the most productive tropical and temperate forest ecosystems of the Earth's vegetated surface through directionally consistent influence on vegetation greenness. The Community Climate System Model ( CCSM4) simulations do not capture the observed patterns of vegetation productivity responses to internal climatic variations. Our analyses show the ubiquitous control of climatic variations on vegetation productivity and can further guide CCSM and other Earth system models developments to represent vegetation response patterns to unforced variability. Several winter time internal climatic variation indices show strong potentials on predicting growing season vegetation productivity two to six seasons ahead which enables national governments and farmers forecast crop yield to ensure supplies of affordable food, famine early warning, and plan management options to minimize yield losses ahead of time. [ABSTRACT FROM AUTHOR]

Published

2016

12. ENSO and NAO affect long‐term leaf litter dynamics and stoichiometry of Scots pine and European beech mixedwoods

Author

Ester González de Andrés, Biing T. Guan, J. Bosco Imbert, Federico J. Castillo, Juan A. Blanco, Yueh-Hsin Lo, Universidad Pública de Navarra. Departamento de Ciencias, and Nafarroako Unibertsitate Publikoa. Zientziak Saila

Subjects

0106 biological sciences, Nutrient cycle, 010504 meteorology & atmospheric sciences, Ecological succession, Nutrient cycling, 010603 evolutionary biology, 01 natural sciences, Trees, Fagus sylvatica, Fagus, medicine, Environmental Chemistry, Beech, Ecosystem, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, Ecology, biology, Phenology, Pyrenees, Scots pine, Leaf litter, Structural equation model (SEM), Pinus sylvestris, Ensemble empirical mode decomposition (EEMD), 15. Life on land, Plant litter, Seasonality, biology.organism_classification, medicine.disease, Stoichiometry, 13. Climate action, Nutrient limitation, Environmental science

Abstract

Litterfall dynamics (production, seasonality and nutrient composition) are key factors influencing nutrient cycling. Leaf litter characteristics are modified by species composition, site conditions and water availability. However, significant evidence on how large-scale, global circulation patterns affect ecophysiological processes at tree and ecosystem level remains scarce due to the difficulty in separating the combined influence of different factors on local climate and tree phenology. To fill this gap, we studied links between leaf litter dynamics with climate and other forest processes, such as tree-ring width (TRW) and intrinsic water-use efficiency (iWUE) in two mixtures of Scots pine (Pinus sylvestris L.) and European beech (Fagus sylvatica L.) in the south-western Pyrenees. Temporal series (18 years) of litterfall production and elemental chemical composition were decomposed following the ensemble empirical mode decomposition (EEMD) method and relationships with local climate, large-scale climatic indices, TRW and Scots pine´s iWUE were assessed. Temporal trends in N:P ratios indicated increasing P-limitation of soil microbes, thus affecting nutrient availability, as the ecological succession from a pine-dominated to a beech-dominated forest took place. A significant influence of large-scale patterns on tree-level ecophysiology was explained through the impact of the North Atlantic Oscillation (NAO) and El Niño – Southern Oscillation (ENSO) on water availability. Positive NAO and negative ENSO were related to dry conditions and, consequently, to early needle shedding and increased N:P ratio of both species. Autumn storm activity appears to be related to premature leaf abscission of European beech. Significant cascading effects from large-scale patterns on local weather influenced pine TRW and iWUE. These variables also responded to leaf stoichiometry fallen three years prior to tree-ring formation. Our results provide evidence of the cascading effect that variability in global climate circulation patterns can have on ecophysiological processes and stand dynamics in mixed forests. Ministerio de Economía y Competitividad, Grant/Award Number: AGL2012-33465, AGL2016-76463-P, BES-2013-066705 and RYC-2011-08082; FP7 People: Marie-Curie Actions, Grant/Award Number: CIG-2012-326718-ECOPYREN3; H2020 Marie Skłodowska-Curie Actions, Grant/Award Number: EF-2014-656810-DENDRONUTRIENT.

Published

2019

13. Wet and dry extremes reduce arthropod biomass independently of leaf phenology in the wet tropics.

Author

Newell FL, Ausprey IJ, and Robinson SK

Subjects

Animals, Tropical Climate, El Nino-Southern Oscillation, Forests, Plant Leaves physiology, Seasons, Trees physiology, Arthropods

Abstract

Warming temperatures are increasing rainfall extremes, yet arthropod responses to climatic fluctuations remain poorly understood. Here, we used spatiotemporal variation in tropical montane climate as a natural experiment to compare the importance of biotic versus abiotic drivers in regulating arthropod biomass. We combined intensive field data on arthropods, leaf phenology and in situ weather across a 1700-3100 m elevation and rainfall gradient, along with desiccation-resistance experiments and multi-decadal modelling. We found limited support for biotic drivers with weak increases in some herbivorous taxa on shrubs with new leaves, but no landscape-scale effects of leaf phenology, which tracked light and cloud cover. Instead, rainfall explained extensive interannual variability with maximum biomass at intermediate rainfall (130 mm month -1 ) as both 3 months of high and low rainfall reduced arthropods by half. Based on 50 years of regional rainfall, our dynamic arthropod model predicted shifts in the timing of biomass maxima within cloud forests before plant communities transition to seasonally deciduous dry forests (mean annual rainfall 1000-2500 mm vs. <800 mm). Rainfall magnitude was the primary driver, but during high solar insolation, the 'drying power of air' (VPD max ) reduced biomass within days contributing to drought related to the El Niño-Southern Oscillation (ENSO). Highlighting risks from drought, experiments demonstrated community-wide susceptibility to desiccation except for some caterpillars in which melanin-based coloration appeared to reduce the effects of evaporative drying. Overall, we provide multiple lines of evidence that several months of heavy rain or drought reduce arthropod biomass independently of deep-rooted plants with the potential to destabilize insectivore food webs., (© 2022 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2023

14. Effects of El Niño drought on seedling dynamics in a seasonally dry tropical forest in Northern Thailand.

Author

Nutiprapun P, Hermhuk S, Nanami S, Itoh A, Kanzaki M, and Marod D

Subjects

El Nino-Southern Oscillation, Forests, Droughts, Thailand, Tropical Climate, Trees, Seedlings

Abstract

As El Niño is predicted to become stronger and more frequent in the future, it is crucial to understand how El Niño-induced droughts will affect tropical forests. Although many studies have focused on tropical rainforests, there is a paucity of studies on seasonally dry tropical forests (SDTFs), particularly in Asia, and few studies have focused on seedling dynamics, which are expected to be strongly affected by drought. Seedlings in SDTFs are generally more drought-tolerant than those in the rainforests, and the effects of El Niño-induced droughts may differ between SDTF and tropical rainforests. In this study, we explored the impact of El Niño-induced drought at an SDTF in northern Thailand by monitoring the seedling dynamics at monthly intervals for 7 years, including a period of strong El Niño. The effects were compared between two forest types in an SDTF: a deciduous dipterocarp forest (DDF), dominated by deciduous species, and an adjacent lower montane forest (LMF) with more evergreen species. El Niño-induced drought increased seedling mortality in both the forest types. The effect of drought was stronger in evergreen than in the deciduous species, resulting in higher mortality in the LMF during El Niño. However, El Niño increased seedling recruitment only in the DDF, mainly because of the massive recruitment of the deciduous oak, Quercus brandisiana (Fagaceae), which compensated for the mortality of seedlings in the DDF. As a result, El Niño increased seedling density in the DDF and decreased it in the LMF. This is the first long-term study to identify the differences in the impacts of El Niño on seedlings between the two forest types, and two leaf habits, evergreen and deciduous, in Southeast Asia. Our findings suggest that future climate change may alter the species composition and spatial distribution of seedlings in Asian SDTFs., (© 2022 John Wiley & Sons Ltd.)

Published

2023

15. Climate change alters the trophic niche of a declining apex marine predator.

Author

Bond, Alexander L. and Lavers, Jennifer L.

Subjects

*STABLE isotopes in ecological research, *FLESH-footed shearwater, *GEOLOGY & climate, *GLOBAL warming, *ENVIRONMENTAL physics, EL Nino

Abstract

Changes in the world's oceans have altered nutrient flow, and affected the viability of predator populations when prey species become unavailable. These changes are integrated into the tissues of apex predators over space and time and can be quantified using stable isotopes in the inert feathers of historical and contemporary avian specimens. We measured δ13C and δ15N values in Flesh-footed Shearwaters ( Puffinus carneipes) from Western and South Australia from 1936-2011. The Flesh-footed Shearwaters more than doubled their trophic niche (from 3.91 ± 1.37 ‰2 to 10.00 ± 1.79 ‰2), and dropped an entire trophic level in 75 years (predicted δ15N decreased from +16.9 ‰ to + 13.5 ‰, and δ13C from −16.9 ‰ to −17.9 ‰) - the largest change in δ15N yet reported in any marine bird, suggesting a relatively rapid shift in the composition of the Indian Ocean food web, or changes in baseline δ13C and δ15N values. A stronger El Niño-Southern Oscillation results in a weaker Leeuwin Current in Western Australia, and decreased Flesh-footed Shearwater δ13C and δ15N. Current climate forecasts predict this trend to continue, leading to increased oceanic 'tropicalization' and potentially competition between Flesh-footed Shearwaters and more tropical sympatric species with expanding ranges. Flesh-footed Shearwater populations are declining, and current conservation measures aimed primarily at bycatch mitigation are not restoring populations. Widespread shifts in foraging, as shown here, may explain some of the reported decline. An improved understanding and ability to mitigate the impacts of global climactic changes is therefore critical to the long-term sustainability of this declining species. [ABSTRACT FROM AUTHOR]

Published

2014

16. Legacies of La Niña: North American monsoon can rescue trees from winter drought

Author

Drew M. P. Peltier and Kiona Ogle

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Climate Change, Rain, Growing season, Monsoon, 010603 evolutionary biology, 01 natural sciences, Trees, Environmental Chemistry, Precipitation, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, Ecology, Cyclonic Storms, North American Monsoon, First order, United States, Droughts, La Niña, Geography, El Niño Southern Oscillation, Climatology, Seasons, Environmental Monitoring

Abstract

While we often assume tree growth-climate relationships are time-invariant, impacts of climate phenomena such as the El Nino Southern Oscillation (ENSO) and the North American Monsoon (NAM) may challenge this assumption. To test this assumption, we grouped ring widths (1900-present) in three southwestern US conifers into La Nina periods (LNP) and other years (OY). The 4 years following each La Nina year are included in LNP, and despite 1-2 year growth declines, compensatory adjustments in tree growth responses result in essentially equal mean growth in LNP and OY, as average growth exceeds OY means 2-4 years after La Nina events. We found this arises because growth responses in the two periods are not interchangeable: Due to differences in growth-climate sensitivities and climatic memory, parameters representing LNP growth fail to predict OY growth and vice versa (decreases in R2 up to 0.63; lowest R2 = 0.06). Temporal relationships between growth and antecedent climate (memory) show warmer springs and longer growing seasons negatively impact growth following dry La Nina winters, but that NAM moisture can rescue trees after these events. Increased importance of monsoonal precipitation during LNP is key, as the largest La Nina-related precipitation deficits and monsoonal precipitation contributions both occur in the southern part of the region. Decreases in first order autocorrelation during LNP were largest in the heart of the monsoon region, reflecting both the greatest initial growth declines and the largest recovery. Understanding the unique climatic controls on growth in Southwest conifers requires consideration of both the influences and interactions of drought, ENSO, and NAM, each of which is likely to change with continued warming. While plasticity of growth sensitivity and memory has allowed relatively quick recovery in the tree-ring record, recent widespread mortality events suggest conditions may soon exceed the capacity for adjustment in current populations.

Published

2018

17. Causes of reduced leaf‐level photosynthesis during strong El Niño drought in a Central Amazon forest

Author

João Victor Figueiredo Cardoso Rodrigues, Victor Alexandre Hardt Ferreira dos Santos, Scott R. Saleska, Maquelle Neves Garcia, João Vitor Barbosa Ceron, Marciel José Ferreira, and Bruce Walker Nelson

Subjects

0106 biological sciences, Canopy, Chlorophyll a, Stomatal conductance, 010504 meteorology & atmospheric sciences, Forests, Biology, Photosynthesis, 01 natural sciences, Trees, chemistry.chemical_compound, parasitic diseases, Dry season, Environmental Chemistry, Chlorophyll fluorescence, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, Ecology, food and beverages, Understory, Droughts, Plant Leaves, chemistry, Agronomy, Chlorophyll, Seasons, Brazil, 010606 plant biology & botany

Abstract

Sustained drought and concomitant high temperature may reduce photosynthesis and cause tree mortality. Possible causes of reduced photosynthesis include stomatal closure and biochemical inhibition, but their relative roles are unknown in Amazon trees during strong drought events. We assessed the effects of the recent (2015) strong El Niño drought on leaf-level photosynthesis of Central Amazon trees via these two mechanisms. Through four seasons of 2015, we measured leaf gas exchange, chlorophyll a fluorescence parameters, chlorophyll concentration, and nutrient content in leaves of 57 upper canopy and understory trees of a lowland terra firme forest on well-drained infertile oxisol. Photosynthesis decreased 28% in the upper canopy and 17% in understory trees during the extreme dry season of 2015, relative to other 2015 seasons and was also lower than the climatically normal dry season of the following non-El Niño year. Photosynthesis reduction under extreme drought and high temperature in the 2015 dry season was related only to stomatal closure in both upper canopy and understory trees, and not to chlorophyll a fluorescence parameters, chlorophyll, or leaf nutrient concentration. The distinction is important because stomatal closure is a transient regulatory response that can reverse when water becomes available, whereas the other responses reflect more permanent changes or damage to the photosynthetic apparatus. Photosynthesis decrease due to stomatal closure during the 2015 extreme dry season was followed 2 months later by an increase in photosynthesis as rains returned, indicating a margin of resilience to one-off extreme climatic events in Amazonian forests.

Published

2018

18. Amazon drought and forest response: Largely reduced forest photosynthesis but slightly increased canopy greenness during the extreme drought of 2015/2016

Author

Jia Yang, Guangsheng Chen, Shree R. S. Dangal, Hanqin Tian, Bowen Zhang, and Shufen Pan

Subjects

0106 biological sciences, Canopy, 010504 meteorology & atmospheric sciences, Forests, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Trees, Carbon cycle, Environmental Chemistry, Ecosystem, Precipitation, Photosynthesis, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, Ecology, Amazon rainforest, Temperature, Vegetation, 15. Life on land, Photosynthetic capacity, Carbon, Droughts, Sea surface temperature, 13. Climate action, Sunlight, Environmental science, Seasons

Abstract

Amazon droughts have impacted regional ecosystem functioning as well as global carbon cycling. The severe dry-season droughts in 2005 and 2010, driven by Atlantic sea surface temperature (SST) anomaly, have been widely investigated in terms of drought severity and impacts on ecosystems. Although the influence of Pacific SST anomaly on wet-season precipitation has been well recognized, it remains uncertain to what extent the droughts driven by Pacific SST anomaly could affect forest greenness and photosynthesis in the Amazon. Here, we examined the monthly and annual dynamics of forest greenness and photosynthetic capacity when Amazon ecosystems experienced an extreme drought in 2015/2016 driven by a strong El Niño event. We found that the drought during August 2015-July 2016 was one of the two most severe meteorological droughts since 1901. Due to the enhanced solar radiation during this drought, overall forest greenness showed a small increase, and 21.6% of forests even greened up (greenness index anomaly ≥1 standard deviation). In contrast, solar-induced chlorophyll fluorescence (SIF), an indicator of vegetation photosynthetic capacity, showed a significant decrease. Responses of forest greenness and photosynthesis decoupled during this drought, indicating that forest photosynthesis could still be suppressed regardless of the variation in canopy greenness. If future El Niño frequency increases as projected by earth system models, droughts would result in persistent reduction in Amazon forest productivity, substantial changes in tree composition, and considerable carbon emissions from Amazon.

Published

2018

19. Linking El Niño, local rainfall, and migration timing in a tropical migratory species.

Author

Shaw, Allison K. and Kelly, Kathryn A.

Subjects

*ATMOSPHERIC models, *MIGRATORY animals, *CLIMATE change, *EMIGRATION & immigration, *GLOBAL temperature changes, *CHACEON

Abstract

Current climate models project changes in both temperature and precipitation patterns across the globe in the coming years. Migratory species, which move to take advantage of seasonal climate patterns, are likely to be affected by these changes, and indeed, a number of studies have shown a relationship between changing climate and the migration timing of various species. However, these studies have almost exclusively focused on the effects of temperature change on species that inhabit temperate zones. Here, we explore the relationship between rainfall and migration timing in a tropical species, Gecarcoidea natalis (Christmas Island red crab). We find that the timing of the annual crab breeding migration is closely related to the amount of rain that falls during a 'migration window' period prior to potential egg release dates, which is in turn related to the Southern Oscillation Index, an atmospheric El Niño- Southern Oscillation Index. As reproduction in this species is conditional on successful migration, major changes in migration patterns could have detrimental consequences for the survival of the species. This study serves to broaden our understanding of the effects of climate change on migratory species and will hopefully inspire future work on rainfall and tropical migrations. [ABSTRACT FROM AUTHOR]

Published

2013

20. Plant hydraulics, stomatal control, and the response of a tropical forest to water stress over multiple temporal scales.

Author

Detto M and Pacala SW

Subjects

Droughts, El Nino-Southern Oscillation, Forests, Plant Leaves physiology, Plants, Soil, Trees physiology, Dehydration, Ecosystem

Abstract

Many tropical regions are experiencing an intensification of drought, with increasing severity and frequency. The ecosystem response to these changes is still highly uncertain. On short time scales (from diurnal to seasonal), tropical forests respond to water stress by physiological controls, such as stomatal regulation and phenological adjustment, to cope with increasing atmospheric water demand and reduced water supply. However, the interactions among biological processes and co-varying environmental factors that determine the ecosystem-level fluxes are still unclear. Furthermore, climate variability at longer time scales, such as that generated by ENSO, produces less predictable effects because it depends on a highly stochastic combination of factors that might vary among forests and even between events in the same forest. This study will present some emerging patterns of response to water stress from 5 years of water, carbon, and energy fluxes observed on a seasonal tropical forest in central Panama, including an increase in productivity during the 2015 El Niño. These responses depend on the combination of environmental factors experienced by the forest throughout the seasonal cycle, in particular, increase in solar radiation, stimulating productivity, and increasing vapor pressure deficit (VPD) and decreasing soil moisture, limiting stomata opening. These results suggest a critical role of plant hydraulics in mediating the response to water stress over a broad range of temporal scales (diurnal, intraseasonal, seasonal, and interannual), by acclimating canopy conductance to light and VPD during different soil moisture regimes. A multilayer photosynthesis model coupled with a plant hydraulics scheme can reproduce these complex responses. However, results depend critically on parameters regulating water transport efficiency and the cost of water stress. As these costs have not been properly identified and quantified yet, more empirical research is needed to elucidate physiological mechanisms of hydraulic failure and recover, for example embolism repair and xylem regrowth., (© 2022 John Wiley & Sons Ltd.)

Published

2022

21. Observed relationships between El Niño-Southern Oscillation, rainfall variability and vegetation and fire history on Halmahera, Maluku, Indonesia.

Author

VAN DER KAARS, SANDER, TAPPER, NIGEL, and COOK, ELLYN J.

Subjects

*VEGETATION & climate, *FIRES, *DISASTERS, *DIPTEROCARPACEAE, *POLLEN, *CARBON, HALMAHERA (Indonesia)

Abstract

A temporally high-resolution palynological study of the uppermost section of core MD98-2180 from Kau Bay, Halmahera, Indonesia, provides a vegetation and fire record covering the last 250 years. The record is compared with the Maluku Rainfall Index, Southern Oscillation Index (SOI) and southern hemisphere winter sea surface temperatures (SST) for the central Pacific Ocean based on instrumental data, as well as reconstructions of the SOI and the central Pacific SST and historically recorded El Niño events. The results show that significant El Niño events are generally associated with increased representation of Dipterocarpaceae pollen, probably reflecting the mass-flowering of this taxon during El Niño-Southern Oscillation (ENSO) droughts, and elevated charcoal levels, reflecting a greater incidence of fires during these extremely dry periods, while humid phases show increased fern numbers. Our findings demonstrate that pollen records ‘ecological’ in scale can provide useful additional proxy records of ENSO events. [ABSTRACT FROM AUTHOR]

Published

2010

22. Climate‐mediated changes in marine ecosystem regulation during El Niño

Author

Ralf Goericke, Mark D. Ohman, David M. Checkley, Martin Lindegren, and J. A. Koslow

Subjects

Pacific Decadal Oscillation, 0106 biological sciences, 010504 meteorology & atmospheric sciences, Climate Change, food web model, Climate change, Forcing (mathematics), 01 natural sciences, California, bottom-up, PDO, SDG 13 - Climate Action, Animals, Environmental Chemistry, Ecosystem, Marine ecosystem, SDG 14 - Life Below Water, El Niño, climate, Life Below Water, 0105 earth and related environmental sciences, General Environmental Science, Trophic level, El Nino-Southern Oscillation, Global and Planetary Change, Ecology, 010604 marine biology & hydrobiology, ecosystem regulation, Fishes, Biological Sciences, Food web, Climate Action, Oceanography, top-down, Upwelling, Environmental science, management, Environmental Sciences, Pacific decadal oscillation, El Nino

Abstract

The degree to which ecosystems are regulated through bottom-up, top-down or direct physical processes represents a long-standing issue in ecology, with important consequences for resource management and conservation. In marine ecosystems, the role of bottom-up and top-down forcing has been shown to vary over spatio-temporal scales, often linked to highly variable and heterogeneously distributed environmental conditions. Ecosystem dynamics in the Northeast Pacific have been suggested to be predominately bottom-up regulated. However, it remains unknown to what extent top-down regulation occurs, or whether the relative importance of bottom-up and top-down forcing may shift in response to climate change. In this study, we investigate the effects and relative importance of bottom-up, top-down and physical forcing during changing climate conditions on ecosystem regulation in the Southern California Current System (SCCS) using a generalized food web model. This statistical approach is based on non-linear threshold models and a long-term data set (~60 year) covering multiple trophic levels from phytoplankton to predatory fish. We found bottom-up control to be the primary mode of ecosystem regulation. However, our results also demonstrate an alternative mode of regulation represented by interacting bottom-up and top-down forcing, analogous to wasp-waist dynamics, but occurring across multiple trophic levels and only during periods of reduced bottom-up forcing (i.e., weak upwelling, low nutrient concentrations and primary production). The shifts in ecosystem regulation are caused by changes in ocean-atmosphere forcing and triggered by highly variable climate conditions associated with El Niño. Furthermore, we show that biota respond differently to major El Niño events during positive or negative phases of the Pacific Decadal Oscillation (PDO), as well as highlight potential concerns for marine and fisheries management by demonstrating increased sensitivity of pelagic fish to exploitation during El Niño. This article is protected by copyright. All rights reserved.

Published

2017

23. A decrease in the abundance and strategic sophistication of cleaner fish after environmental perturbations

Author

Zegni Triki, Elena Levorato, Redouan Bshary, and Sharon Wismer

Subjects

0106 biological sciences, Coral bleaching, Coral reef fish, Population Dynamics, Cleaner fish, 010603 evolutionary biology, 01 natural sciences, Extreme weather, Animals, Environmental Chemistry, 14. Life underwater, Labroides, Symbiosis, Fish intelligence, General Environmental Science, El Nino-Southern Oscillation, Mutualism (biology), Global and Planetary Change, geography.geographical_feature_category, Ecology, biology, Coral Reefs, 010604 marine biology & hydrobiology, Fishes, Coral reef, biology.organism_classification, Fishery, Geography, 13. Climate action

Abstract

Coral reef ecosystems are declining worldwide and under foreseeable threat due to climate change, resulting in significant changes in reef communities. It is unknown, however, how such community changes impact interspecific interactions. Recent extreme weather events affecting the Great Barrier Reef, that is, consecutive cyclones and the 2016 El Niño event, allowed us to explore potential consequences in the mutualistic interactions involving cleaner fish Labroides dimidiatus (hereafter "cleaner"). After the perturbations, cleaner densities were reduced by 80%, disproportionally compared to the variety of reef fish clients from which cleaners remove ectoparasites. Consequently, shifts in supply and demand yielded an increase in the clients' demand for cleaning. Therefore, clients became less selective toward cleaners, whereas cleaners were able to choose from a multitude of partners. In parallel, we found a significant decline in the ability of cleaners to manage their reputation and to learn to prioritize ephemeral food sources to maximize food intake in laboratory experiments. In other words, cleaners failed to display the previously documented strategic sophistication that made this species a prime example for fish intelligence. In conclusion, low population densities may cause various effects on individual behavior, and as a consequence, interspecific interactions. At the same time, our data suggest that a recovery of population densities would cause a recovery of previously described interaction patterns and cleaner strategic sophistication within the lifetime of individuals.

Published

2017

24. Spatial evaluation of Indonesia's 2015 fire‐affected area and estimated carbon emissions using Sentinel‐1

Author

Sandra Lohberger, Matthias Stängel, Elizabeth C. Atwood, and Florian Siegert

Subjects

Synthetic aperture radar, Haze, Peat, 010504 meteorology & atmospheric sciences, Meteorology, Land cover, 010501 environmental sciences, 01 natural sciences, Fires, Fire control, Environmental Chemistry, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Air Pollutants, Global and Planetary Change, Ecology, Land use, Anomaly (natural sciences), Carbon Dioxide, Satellite Communications, Carbon, Droughts, Indonesia, Greenhouse gas, Environmental science, Physical geography

Abstract

Fires raged once again across Indonesia in the latter half of 2015, creating a state of emergency due to poisonous smoke and haze across Southeast Asia as well as incurring great financial costs to the government. A strong El Nino-Southern Oscillation (ENSO) led to drought in many parts of Indonesia, resulting in elevated fire occurrence comparable with the previous catastrophic event in 1997/98. Synthetic Aperture Radar (SAR) data promise to provide improved detection of land use and land cover changes in the tropics as compared to methodologies dependent upon cloud and haze free images. This study presents the first spatially explicit estimates of burned area across Sumatra, Kalimantan and West Papua based on high resolution Sentinel-1A SAR imagery. Here we show that 4,604,569 hectares (ha) were burned during the 2015 fire season (overall accuracy 84 %), and compare this with other existing operational burned area products (MCD64, GFED4.0, GFED4.1s). Intersection of burned area with fine-scale land cover and peat layer maps indicates that 0.89 gigatons carbon dioxide equivalents (Gt CO2e) were released through the fire event. This result is compared to other estimates based on non-spatially explicit thermal anomaly measurements or atmospheric monitoring. Using freely available SAR C-band data from the Sentinel mission, we argue that the presented methodology is able to quickly and precisely detect burned areas, supporting improvement in fire control management as well as enhancing accuracy of emissions estimation. This article is protected by copyright. All rights reserved.

Published

2017

25. Climatic effects on the phenology of lake processes.

Author

Winder, Monika and Schindler, Daniel E.

Subjects

*LAKES, *CLIMATE change, *PHENOLOGY, *PHYTOPLANKTON

Abstract

Populations living in seasonal environments are exposed to systematic changes in physical conditions that restrict the growth and reproduction of many species to only a short time window of the annual cycle. Several studies have shown that climate changes over the latter part of the 20th century affected the phenology and population dynamics of single species. However, the key limitation to forecasting the effects of changing climate on ecosystems lies in understanding how it will affect interactions among species. We investigated the effects of climatic and biotic drivers on physical and biological lake processes, using a historical dataset of 40 years from Lake Washington, USA, and dynamic time-series models to explain changes in the phenological patterns among physical and biological components of pelagic ecosystems. Long-term climate warming and variability because of large-scale climatic patterns like Pacific decadal oscillation (PDO) and El Niño-southern oscillation (ENSO) extended the duration of the stratification period by 25 days over the last 40 years. This change was due mainly to earlier spring stratification (16 days) and less to later stratification termination in fall (9 days). The phytoplankton spring bloom advanced roughly in parallel to stratification onset and in 2002 it occurred about 19 days earlier than it did in 1962, indicating the tight connection of spring phytoplankton growth to turbulent conditions. In contrast, the timing of the clear-water phase showed high variability and was mainly driven by biotic factors. Among the zooplankton species, the timing of spring peaks in the rotifer Keratella advanced strongly, whereas Leptodiaptomus and Daphnia showed slight or no changes. These changes have generated a growing time lag between the spring phytoplankton peak and zooplankton peak, which can be especially critical for the cladoceran Daphnia. Water temperature, PDO, and food availability affected the timing of the spring peak in zooplankton. Overall, the impact of PDO on the phenological processes were stronger compared with ENSO. Our results highlight that climate affects physical and biological processes differently, which can interrupt energy flow among trophic levels, making ecosystem responses to climate change difficult to forecast. [ABSTRACT FROM AUTHOR]

Published

2004

26. Teleconnection between tree growth in the Amazonian floodplains and the El Niño–Southern Oscillation effect.

Author

Schöngart, Jochen, Junk, Wolfgang J., Piedade, Maria Teresa F., Ayres, José Marcio, Hüttermann, Aloys, and Worbes, Martin

Subjects

*TREE growth, *FOREST ecology, *FLOODPLAINS, *SOUTHERN oscillation, *ATMOSPHERIC pressure, EL Nino

Abstract

There is a limited knowledge about the El Niño–Southern Oscillation (ENSO) effects on the Amazon basin, the world's largest tropical rain forest and a major factor in the global carbon cycle. Seasonal precipitation in the Andean watershed annually causes a several month-long inundation of the floodplains along the Amazon River that induces the formation of annual rings in trees of the flooded forests. Radial growth of trees is mainly restricted to the nonflooded period and thus the ring width corresponds to its duration. This allows the construction of a tree-ring chronology of the long-living hardwood species Piranhea trifoliata Baill. (Euphorbiaceae). El Niño causes anomalously low precipitation in the catchment that results in a significantly lower water discharge of the Amazon River and consequently in an extension of the vegetation period. In those years tree rings are significantly wider. Thus the tree-ring record can be considered as a robust indicator reflecting the mean climate conditions of the whole Western Amazon basin. We present a more than 200-year long chronology, which is the first ENSO-sensitive dendroclimatic proxy of the Amazon basin and permits the dating of preinstrumental El Niño events. Time series analyses of our data indicate that during the last two centuries the severity of El Niño increased significantly. [ABSTRACT FROM AUTHOR]

Published

2004

27. El Niño and tree growth near Jerusalem over the last 20 years.

Author

Lev-Yadun, Simcha, Yakir, Dan, and Zangvil, Avraham

Subjects

*PLANT growth, *RAINFALL

Published

1996

28. The effects of El Niño-Southern Oscillation events on intertidal seagrass beds over a long-term timescale

Author

Shang‐En Peng, Pi-Jen Liu, Chen-Lu Lee, Meng‐Chi Hung, Anderson B. Mayfield, and Hsing-Juh Lin

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Nitrogen, Intertidal zone, Hydrocharitaceae, 01 natural sciences, Environmental Chemistry, Ecosystem, Seawater, Biomass, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, Biomass (ecology), Ecology, biology, 010604 marine biology & hydrobiology, Eutrophication, biology.organism_classification, Plant Leaves, La Niña, Oceanography, Seagrass, Habitat, Productivity (ecology), Halodule uninervis, Environmental science

Abstract

El Nino-Southern Oscillation (ENSO) events can cause dramatic changes in marine communities. However, we know little as to how ENSO events affect tropical seagrass beds over decadal timescales. Therefore, a diverse array of seagrass (Thalassia hemprichii) habitat types were surveyed once every 3 months for 16 years (January 2001 to February 2017) in a tropical intertidal zone that is regularly affected by both ENSO events and anthropogenic nutrient enrichment. La Nina and El Nino events had distinct effects on the biomass and growth of T. hemprichii. During La Nina years, higher (a) precipitation levels and (b) seawater nitrogen concentrations led to increases in seagrass leaf productivity, canopy height, and biomass. However, the latter simultaneously stimulated the growth of periphyton on seagrass leaves; this led to decreases in seagrass cover and shoot density. More frequent La Nina events could, then, eventually lead to either a decline in intertidal seagrass beds or a shift to another, less drought-resistant seagrass species in those regions already characterized by eutrophication due to local anthropogenic activity.

Published

2018

29. Albatrosses respond adaptively to climate variability by changing variance in a foraging trait.

Author

Patrick SC, Martin JGA, Ummenhofer CC, Corbeau A, and Weimerskirch H

Subjects

Animals, Climate Change, El Nino-Southern Oscillation, Humans, Population Dynamics, Birds, Reproduction

Abstract

The ability of individuals and populations to adapt to a changing climate is a key determinant of population dynamics. While changes in mean behaviour are well studied, changes in trait variance have been largely ignored, despite being assumed to be crucial for adapting to a changing environment. As the ability to acquire resources is essential to both reproduction and survival, changes in behaviours that maximize resource acquisition should be under selection. Here, using foraging trip duration data collected over 7 years on black-browed albatrosses (Thalassarche melanophris) on the Kerguelen Islands in the southern Indian Ocean, we examined the importance of changes in the mean and variance in foraging behaviour, and the associated effects on fitness, in response to the El Niño Southern Oscillation (ENSO). Using double hierarchical models, we found no evidence that individuals change their mean foraging trip duration in response to a changing environment, but found strong evidence of changes in variance. Younger birds showed greater variability in foraging trip duration in poor conditions as did birds with higher fitness. However, during brooding, birds showed greater variability in foraging behaviour under good conditions, suggesting that optimal conditions allow the alteration between chick provisioning and self-maintenance trips. We found weak correlations between sea surface temperature and the ENSO, but stronger links with sea-level pressure. We suggest that variability in behavioural traits affecting resource acquisition is under selection and offers a mechanism by which individuals can adapt to a changing climate. Studies which look only at effects on mean behaviour may underestimate the effects of climate change and fail to consider variance in traits as a key evolutionary force., (© 2021 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2021

30. Increased mortality of tropical tree seedlings during the extreme 2015-16 El Niño.

Author

Browne L, Markesteijn L, Engelbrecht BMJ, Jones FA, Lewis OT, Manzané-Pinzón E, Wright SJ, and Comita LS

Subjects

Droughts, Forests, Seasons, Seedlings, Tropical Climate, El Nino-Southern Oscillation, Trees

Abstract

As extreme climate events are predicted to become more frequent because of global climate change, understanding their impacts on natural systems is crucial. Tropical forests are vulnerable to droughts associated with extreme El Niño events. However, little is known about how tropical seedling communities respond to El Niño-related droughts, even though patterns of seedling survival shape future forest structure and diversity. Using long-term data from eight tropical moist forests spanning a rainfall gradient in central Panama, we show that community-wide seedling mortality increased by 11% during the extreme 2015-16 El Niño, with mortality increasing most in drought-sensitive species and in wetter forests. These results indicate that severe El Niño-related droughts influence understory dynamics in tropical forests, with effects varying both within and across sites. Our findings suggest that predicted increases in the frequency of extreme El Niño events will alter tropical plant communities through their effects on early life stages., (© 2021 John Wiley & Sons Ltd.)

Published

2021

31. Unusual characteristics of the carbon cycle during the 2015-2016 El Niño.

Author

Wang K, Wang X, Piao S, Chevallier F, Mao J, Shi X, Huntingford C, Bastos A, Ciais P, Xu H, Keeling RF, Pacala SW, and Chen A

Subjects

Atmosphere, Carbon, Carbon Cycle, Carbon Dioxide, Ecosystem, El Nino-Southern Oscillation

Abstract

The 2015-2016 El Niño was one of the strongest on record, but its influence on the carbon balance is less clear. Using Northern Hemisphere atmospheric CO 2 observations, we found both detrended atmospheric CO 2 growth rate (CGR) and CO 2 seasonal-cycle amplitude (SCA) of 2015-2016 were much higher than that of other El Niño events. The simultaneous high CGR and SCA were unusual, because our analysis of long-term CO 2 observations at Mauna Loa revealed a significantly negative correlation between CGR and SCA. Atmospheric inversions and terrestrial ecosystem models indicate strong northern land carbon uptake during spring but substantially reduced carbon uptake (or high emissions) during early autumn, which amplified SCA but also resulted in a small anomaly in annual carbon uptake of northern ecosystems in 2015-2016. This negative ecosystem carbon uptake anomaly in early autumn was primarily due to soil water deficits and more litter decomposition caused by enhanced spring productivity. Our study demonstrates a decoupling between seasonality and annual carbon cycle balance in northern ecosystems over 2015-2016, which is unprecedented in the past five decades of El Niño events., (© 2021 John Wiley & Sons Ltd.)

Published

2021

32. The Indian Ocean Dipole and El Niño Southern Oscillation as major drivers of coral cover on shallow reefs in the Andaman Sea.

Author

Dunne RP, Brown BE, Phongsuwan N, and Putchim L

Subjects

Animals, Coral Reefs, El Nino-Southern Oscillation, Indian Ocean, Indonesia, Thailand, Anthozoa

Abstract

Shallow reefs are a major feature of coral assemblages in the Andaman Sea. At Phuket, Thailand sheltered reefs are dominated by massive corals, together with an increasing abundance of branching species during favourable growth conditions. The growth of coral on these reefs is moderated by long-term increases in sea temperature and relative sea level but fluctuating decadal/intradecadal climate processes of El Niño Southern Oscillation (ENSO) and Indian Ocean Dipole (IOD), which modulate sea level and temperature, are the main drivers of coral cover. In this study, the contribution of these two climate processes was identified and also quantified. Over a 34-year study of fluctuating coral cover, the three major reductions in cover in 1997, 2010 and 2019 were linked to overlapping positive IOD (pIOD) and El Niños in 1997 and 2019, and with an El Niño alone in 2010. Combined pIOD and El Niño depressed sea level was the major factor in reducing cover in 1997 while El Niño extreme sea temperatures were responsible for large reductions in 2010. In 2019, a bi-phasic pIOD and El Niño resulted in lowered cover at a time of both decreased sea level and high sea temperature. Under global warming scenarios, it is projected that extreme pIODs, such as those seen in 1997 and 2019, will occur more frequently while El Niño frequencies will continue to increase even after global mean temperature stabilization. In these circumstances, and with steadily rising background sea temperatures, the future risks to the shallow reefs of the Andaman Sea are substantial, despite any temporary respite gained from climate related or land subsidence sea-level rise. Such findings have wider implications for all reefs affected by climatic-driven sea-level depressions, particularly those around Indonesian shores where similar El-Niño-related reductions in coral cover have been reported., (© 2021 John Wiley & Sons Ltd.)

Published

2021

33. Rising synchrony controls western North American ecosystems

Author

Steven J. Bograd, Marisol García-Reyes, Mohammad Safeeq, Bryan A. Black, Ivan Arismendi, Ryan R. Rykaczewski, Daniel Griffin, Peter van der Sleen, William J. Sydeman, Emanuele Di Lorenzo, and Jason B. Dunham

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Climate Change, North Pacific High, Context (language use), 010603 evolutionary biology, 01 natural sciences, Rivers, Environmental Chemistry, Ecosystem, Quercus douglasii, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, Extinction, Ecology, biology, biology.organism_classification, United States, Geography, Upwelling, Storm track, Terrestrial ecosystem, Seasons, Environmental Monitoring

Abstract

Along the western margin of North America, the winter expression of the North Pacific High (NPH) strongly influences interannual variability in coastal upwelling, storm track position, precipitation, and river discharge. Coherence among these factors induces covariance among physical and biological processes across adjacent marine and terrestrial ecosystems. Here, we show that over the past century the degree and spatial extent of this covariance (synchrony) has substantially increased, and is coincident with rising variance in the winter NPH. Furthermore, centuries-long blue oak (Quercus douglasii) growth chronologies sensitive to the winter NPH provide robust evidence that modern levels of synchrony are among the highest observed in the context of the last 250 years. These trends may ultimately be linked to changing impacts of the El Nino Southern Oscillation on midlatitude ecosystems of North America. Such a rise in synchrony may destabilize ecosystems, expose populations to higher risks of extinction, and is thus a concern given the broad biological relevance of winter climate to biological systems.

Published

2017

34. El Niño Southern Oscillation influences the abundance and movements of a marine top predator in coastal waters

Author

Kate R. Sprogis, Fredrik Christiansen, Lars Bejder, and Moritz Wandres

Subjects

0106 biological sciences, Population, Population Dynamics, 010603 evolutionary biology, 01 natural sciences, Marine mammal, Environmental Chemistry, Tursiops aduncus, Animals, Marine ecosystem, education, Ecosystem, General Environmental Science, Apex predator, El Nino-Southern Oscillation, Global and Planetary Change, education.field_of_study, Ecology, biology, 010604 marine biology & hydrobiology, Temperature, Western Australia, biology.organism_classification, Bottlenose dolphin, Bottle-Nosed Dolphin, La Niña, Sea surface temperature, Oceanography, Predatory Behavior, Environmental science, Seasons, Animal Distribution

Abstract

Large-scale climate modes such as El Nino Southern Oscillation (ENSO) influence population dynamics in many species, including marine top predators. However, few quantitative studies have investigated the influence of large-scale variability on resident marine top predator populations. We examined the effect of climate variability on the abundance and temporary emigration of a resident bottlenose dolphin (Tursiops aduncus) population off Bunbury, Western Australia (WA). This population has been studied intensively over six consecutive years (2007–2013), yielding a robust dataset that captures seasonal variations in both abundance and movement patterns. In WA, ENSO affects the strength of the Leeuwin Current (LC), the dominant oceanographic feature in the region. The strength and variability of the LC affects marine ecosystems and distribution of top predator prey. We investigated the relationship between dolphin abundance and ENSO, Southern Annular Mode, austral season, rainfall, sea surface salinity and sea surface temperature (SST). Linear models indicated that dolphin abundance was significantly affected by ENSO, and that the magnitude of the effect was dependent upon season. Dolphin abundance was lowest during winter 2009, when dolphins had high temporary emigration rates out of the study area. This coincided with the single El Nino event that occurred throughout the study period. Coupled with this event, there was a negative anomaly in SST and an above average rainfall. These conditions may have affected the distribution of dolphin prey, resulting in the temporary emigration of dolphins out of the study area in search of adequate prey. This study demonstrated the local effects of large-scale climatic variations on the short-term response of a resident, coastal delphinid species. With a projected global increase in frequency and intensity of extreme climatic events, resident marine top predators may not only have to contend with increasing coastal anthropogenic activities, but also have to adapt to large-scale climatic changes.

Published

2017

35. Carbon accumulation of tropical peatlands over millennia: a modeling approach

Author

Boone Kauffman, Julie Talbot, Sofyan Kurnianto, Daniel Murdiyarso, M.W. Warren, and Steve Frolking

Subjects

Peat, chemistry.chemical_element, Soil science, Carbon sequestration, Models, Biological, Carbon Cycle, Carbon cycle, Soil, Deforestation, Environmental Chemistry, Computer Simulation, Photosynthesis, Groundwater, General Environmental Science, El Nino-Southern Oscillation, Hydrology, Tropical Climate, Global and Planetary Change, Ecology, Primary production, Vegetation, Peat swamp forest, Carbon, chemistry, Environmental science

Abstract

Tropical peatlands cover an estimated 440,000 km2 (~10% of global peatland area) and are significant in the global carbon cycle by storing about 40-90 Gt C in peat. Over the past several decades, tropical peatlands have experienced high rates of deforestation and conversion, which is often associated with lowering the water table and peat burning, releasing large amounts of carbon stored in peat to the atmosphere. We present the first model of long-term carbon accumulation in tropical peatlands by modifying the Holocene Peat Model (HPM), which has been successfully applied to northern temperate peatlands. Tropical HPM (HPMTrop) is a one-dimensional, nonlinear, dynamic model with a monthly time step that simulates peat mass remaining in annual peat cohorts over millennia as a balance between monthly vegetation inputs (litter) and monthly decomposition. Key model parameters were based on published data on vegetation characteristics, including net primary production partitioned into leaves, wood, and roots; and initial litter decomposition rates. HPMTrop outputs are generally consistent with field observations from Indonesia. Simulated long-term carbon accumulation rates for 11,000-year-old inland, and 5000-year-old coastal peatlands were about 0.3 and 0.59 Mg C ha(-1) yr(-1), and the resulting peat carbon stocks at the end of the 11,000-year and 5000-year simulations were 3300 and 2900 Mg C ha(-1), respectively. The simulated carbon loss caused by coastal peat swamp forest conversion into oil palm plantation with periodic burning was 1400 Mg C ha(-1) over 100 years, which is equivalent to ~2900 years of C accumulation in a hectare of coastal peatlands.

Published

2014

36. Climate change alters the trophic niche of a declining apex marine predator

Author

Alexander L. Bond and Jennifer L. Lavers

Subjects

Food Chain, Time Factors, Climate Change, Climate change, Biology, Shearwater, Predation, Birds, South Australia, Animals, Environmental Chemistry, Puffinus carneipes, General Environmental Science, Trophic level, Apex predator, Isotope analysis, El Nino-Southern Oscillation, Carbon Isotopes, Global and Planetary Change, Nitrogen Isotopes, Ecology, Feeding Behavior, Western Australia, Feathers, biology.organism_classification, Food web, Seasons

Abstract

Changes in the world's oceans have altered nutrient flow, and affected the viability of predator populations when prey species become unavailable. These changes are integrated into the tissues of apex predators over space and time and can be quantified using stable isotopes in the inert feathers of historical and contemporary avian specimens. We measured δ(13) C and δ(15) N values in Flesh-footed Shearwaters (Puffinus carneipes) from Western and South Australia from 1936-2011. The Flesh-footed Shearwaters more than doubled their trophic niche (from 3.91 ± 1.37 ‰(2) to 10.00 ± 1.79 ‰(2) ), and dropped an entire trophic level in 75 years (predicted δ(15) N decreased from +16.9 ‰ to + 13.5 ‰, and δ(13) C from -16.9 ‰ to -17.9 ‰) - the largest change in δ(15) N yet reported in any marine bird, suggesting a relatively rapid shift in the composition of the Indian Ocean food web, or changes in baseline δ(13) C and δ(15) N values. A stronger El Niño-Southern Oscillation results in a weaker Leeuwin Current in Western Australia, and decreased Flesh-footed Shearwater δ(13) C and δ(15) N. Current climate forecasts predict this trend to continue, leading to increased oceanic 'tropicalization' and potentially competition between Flesh-footed Shearwaters and more tropical sympatric species with expanding ranges. Flesh-footed Shearwater populations are declining, and current conservation measures aimed primarily at bycatch mitigation are not restoring populations. Widespread shifts in foraging, as shown here, may explain some of the reported decline. An improved understanding and ability to mitigate the impacts of global climactic changes is therefore critical to the long-term sustainability of this declining species.

Published

2014

37. Evidence for climate-driven synchrony of marine and terrestrial ecosystems in northwest Australia

Author

Jens Zinke, Mark G. Meekan, Stephen J. Newman, Alison J. O'Donnell, Joyce J. L. Ong, Janice M. Lough, Adam N. Rountrey, Jessica J. Meeuwig, Pauline F. Grierson, and Mélissa Trougan

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Climate, Climate Change, Callitris columellaris, Porites, Climate change, 01 natural sciences, Effects of global warming, Dendrochronology, Environmental Chemistry, Animals, Southern Hemisphere, Ecosystem, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, Ecology, biology, 010604 marine biology & hydrobiology, Australia, biology.organism_classification, Anthozoa, La Niña, Oceanography, Terrestrial ecosystem

Abstract

The effects of climate change are difficult to predict for many marine species because little is known of their response to climate variations in the past. However, long-term chronologies of growth, a variable that integrates multiple physical and biological factors, are now available for several marine taxa. These allow us to search for climate-driven synchrony in growth across multiple taxa and ecosystems, identifying the key processes driving biological responses at very large spatial scales. We hypothesized that in northwest (NW) Australia, a region that is predicted to be strongly influenced by climate change, the El Nino Southern Oscillation (ENSO) phenomenon would be an important factor influencing the growth patterns of organisms in both marine and terrestrial environments. To test this idea, we analyzed existing growth chronologies of the marine fish Lutjanus argentimaculatus, the coral Porites spp. and the tree Callitris columellaris and developed a new chronology for another marine fish, Lethrinus nebulosus. Principal components analysis and linear model selection showed evidence of ENSO-driven synchrony in growth among all four taxa at interannual time scales, the first such result for the Southern Hemisphere. Rainfall, sea surface temperatures, and sea surface salinities, which are linked to the ENSO system, influenced the annual growth of fishes, trees, and corals. All four taxa had negative relationships with the Nino-4 index (a measure of ENSO status), with positive growth patterns occurring during strong La Nina years. This finding implies that future changes in the strength and frequency of ENSO events are likely to have major consequences for both marine and terrestrial taxa. Strong similarities in the growth patterns of fish and trees offer the possibility of using tree-ring chronologies, which span longer time periods than those of fish, to aid understanding of both historical and future responses of fish populations to climate variation.

Published

2016

38. Unchartered waters: Climate change likely to intensify infectious disease outbreaks causing mass mortality events in marine mammals.

Author

Sanderson CE and Alexander KA

Subjects

Animals, Disease Outbreaks, Ecosystem, El Nino-Southern Oscillation, Mammals, Caniformia, Climate Change

Abstract

Infectious disease emergence has increased significantly over the last 30 years, with mass mortality events (MMEs) associated with epizootics becoming increasingly common. Factors influencing these events have been widely studied in terrestrial systems, but remain relatively unexplored in marine mammals. Infectious disease-induced MMEs (ID MMEs) have not been reported ubiquitously among marine mammal species, indicating that intrinsic (host) and/or extrinsic (environmental) ecological factors may influence this heterogeneity. We assess the occurrence of ID MMEs (1955-2018) across extant marine mammals (n = 129) in relation to key life-history characteristics (sociality, trophic level, habitat breadth) and environmental variables (season, sea surface temperature [SST] anomalies, El Niño occurrence). Our results show that ID MMEs have been reported in 14% of marine mammal species (95% CI 9%-21%), with 72% (n = 36; 95% CI 56%-84%) of these events caused predominantly by viruses, primarily morbillivirus and influenza A. Bacterial pathogens caused 25% (95% CI 14%-41%) of MMEs, with only one being the result of a protozoan pathogen. Overall, virus-induced MMEs involved a greater number of fatalities per event compared to other pathogens. No association was detected between the occurrence of ID MMEs and host characteristics, such as sociality or trophic level, but ID MMEs did occur more frequently in semiaquatic species (pinnipeds) compared to obligate ocean dwellers (cetaceans; χ 2  = 9.6, p = .002). In contrast, extrinsic factors significantly influenced ID MMEs, with seasonality linked to frequency (χ 2  = 19.85, p = .0002) and severity of these events, and global yearly SST anomalies positively correlated with their temporal occurrence (Z = 3.43, p = 2.7e-04). No significant association was identified between El Niño and ID MME occurrence (Z = 0.28, p = .81). With climate change forecasted to increase SSTs and the frequency of extreme seasonal weather events, epizootics causing MMEs are likely to intensify with significant consequences for marine mammal survival., (© 2020 John Wiley & Sons Ltd.)

Published

2020

39. Coral reef resilience to thermal stress in the Eastern Tropical Pacific.

Author

Romero-Torres M, Acosta A, Palacio-Castro AM, Treml EA, Zapata FA, Paz-García DA, and Porter JW

Subjects

Animals, Climate Change, Ecuador, El Nino-Southern Oscillation, Anthozoa, Coral Reefs

Abstract

Coral reefs worldwide are threatened by thermal stress caused by climate change. Especially devastating periods of coral loss frequently occur during El Niño-Southern Oscillation (ENSO) events originating in the Eastern Tropical Pacific (ETP). El Niño-induced thermal stress is considered the primary threat to ETP coral reefs. An increase in the frequency and intensity of ENSO events predicted in the coming decades threatens a pan-tropical collapse of coral reefs. During the 1982-1983 El Niño, most reefs in the Galapagos Islands collapsed, and many more in the region were decimated by massive coral bleaching and mortality. However, after repeated thermal stress disturbances, such as those caused by the 1997-1998 El Niño, ETP corals reefs have demonstrated regional persistence and resiliency. Using a 44 year dataset (1970-2014) of live coral cover from the ETP, we assess whether ETP reefs exhibit the same decline as seen globally for other reefs. Also, we compare the ETP live coral cover rate of change with data from the maximum Degree Heating Weeks experienced by these reefs to assess the role of thermal stress on coral reef survival. We find that during the period 1970-2014, ETP coral cover exhibited temporary reductions following major ENSO events, but no overall decline. Further, we find that ETP reef recovery patterns allow coral to persist under these El Niño-stressed conditions, often recovering from these events in 10-15 years. Accumulative heat stress explains 31% of the overall annual rate of change of living coral cover in the ETP. This suggests that ETP coral reefs have adapted to thermal extremes to date, and may have the ability to adapt to near-term future climate-change thermal anomalies. These findings for ETP reef resilience may provide general insights for the future of coral reef survival and recovery elsewhere under intensifying El Niño scenarios., (© 2020 John Wiley & Sons Ltd.)

Published

2020

40. A catastrophic tropical drought kills hydraulically vulnerable tree species.

Author

Powers JS, Vargas G G, Brodribb TJ, Schwartz NB, Pérez-Aviles D, Smith-Martin CM, Becknell JM, Aureli F, Blanco R, Calderón-Morales E, Calvo-Alvarado JC, Calvo-Obando AJ, Chavarría MM, Carvajal-Vanegas D, Jiménez-Rodríguez CD, Murillo Chacon E, Schaffner CM, Werden LK, Xu X, and Medvigy D

Subjects

Costa Rica, Forests, Plant Leaves, Tropical Climate, Droughts, El Nino-Southern Oscillation

Abstract

Drought-related tree mortality is now a widespread phenomenon predicted to increase in magnitude with climate change. However, the patterns of which species and trees are most vulnerable to drought, and the underlying mechanisms have remained elusive, in part due to the lack of relevant data and difficulty of predicting the location of catastrophic drought years in advance. We used long-term demographic records and extensive databases of functional traits and distribution patterns to understand the responses of 20-53 species to an extreme drought in a seasonally dry tropical forest in Costa Rica, which occurred during the 2015 El Niño Southern Oscillation event. Overall, species-specific mortality rates during the drought ranged from 0% to 34%, and varied little as a function of tree size. By contrast, hydraulic safety margins correlated well with probability of mortality among species, while morphological or leaf economics spectrum traits did not. This firmly suggests hydraulic traits as targets for future research., (© 2020 John Wiley & Sons Ltd.)

Published

2020

41. Global vegetation productivity response to climatic oscillations during the satellite era

Author

Danica Lombardozzi, Jing M. Chen, and Alemu Gonsamo

Subjects

010504 meteorology & atmospheric sciences, Climate Change, 0208 environmental biotechnology, 02 engineering and technology, 01 natural sciences, Normalized Difference Vegetation Index, Russia, medicine, Environmental Chemistry, Productivity, Ecosystem, 0105 earth and related environmental sciences, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, Ecology, Global warming, Temperature, Temperate forest, 020801 environmental engineering, La Niña, Climatology, Spatial ecology, Environmental science, Community Climate System Model, Seasons, medicine.symptom, Vegetation (pathology)

Abstract

Climate control on global vegetation productivity patterns has intensified in response to recent global warming. Yet, the contributions of the leading internal climatic variations to global vegetation productivity are poorly understood. Here, we use 30 years of global satellite observations to study climatic variations controls on continental and global vegetation productivity patterns. El Nino-Southern Oscillation (ENSO) phases (La Nina, neutral, and El Nino years) appear to be a weaker control on global-scale vegetation productivity than previously thought, although continental-scale responses are substantial. There is also clear evidence that other non-ENSO climatic variations have a strong control on spatial patterns of vegetation productivity mainly through their influence on temperature. Among the eight leading internal climatic variations, the East Atlantic/West Russia Pattern extensively controls the ensuing year vegetation productivity of the most productive tropical and temperate forest ecosystems of the Earth's vegetated surface through directionally consistent influence on vegetation greenness. The Community Climate System Model (CCSM4) simulations do not capture the observed patterns of vegetation productivity responses to internal climatic variations. Our analyses show the ubiquitous control of climatic variations on vegetation productivity and can further guide CCSM and other Earth system models developments to represent vegetation response patterns to unforced variability. Several winter time internal climatic variation indices show strong potentials on predicting growing season vegetation productivity two to six seasons ahead which enables national governments and farmers forecast crop yield to ensure supplies of affordable food, famine early warning, and plan management options to minimize yield losses ahead of time.

Published

2015

42. The impact of El Niño events on the pelagic food chain in the northern California Current

Author

Jennifer L. Fisher, Ryan R. Rykaczewski, and William T. Peterson

Subjects

El Nino-Southern Oscillation, Global and Planetary Change, Food Chain, Hot Temperature, Pacific Ocean, Ecology, Ocean current, Climate change, Pelagic zone, Biodiversity, Plankton, Zooplankton, California, Copepoda, Food chain, Oceanography, Environmental Chemistry, Environmental science, Animals, Ecosystem, Seasons, Pacific decadal oscillation, General Environmental Science

Abstract

The zooplankton of the northern California Current are typically characterized by an abundance of lipid-rich copepods that support rapid growth and survival of ecologically, commercially, and recreationally valued fish, birds, and mammals. Disruption of this food chain and reduced ecosystem productivity are often associated with climatic variability such as El Nino events. We examined the variability in timing, magnitude, and duration of positive temperature anomalies and changes in copepod species composition in the northern California Current in relation to 10 tropical El Nino events. Measurable impacts on mesozooplankton of the northern California Current were observed during seven of 10 of these events. The occurrence of anomalously warm water and the response of the copepod community was rapid (lag of zero to 2 months) following the initiation of canonical Eastern Pacific (EP) events, but delayed (lag of 2-8 months) following 'Modoki' Central Pacific (CP) events. The variable lags in the timing of a physical and biological response led to impacts in the northern California Current peaking in winter during EP events and in the spring during CP events. The magnitude and duration of the temperature and copepod anomalies were strongly and positively related to the magnitude and duration of El Nino events, but were also sensitive to the phase of the lower frequency Pacific Decadal Oscillation. When fisheries managers and biological oceanographers are faced with the prospect of a future El Nino event, prudent management and observation will require consideration of the background oceanographic conditions, the type of event, and both the magnitude and duration of the event when assessing the potential physical and biological impacts on the northern California Current.

Published

2015

43. Decadal-scale rates of reef erosion following El Niño-related mass coral mortality

Author

George Roff, Peter J. Mumby, and Jian-xin Zhao

Subjects

Coral bleaching, Numerical response, Coral, Climate Change, Climate change, Biology, Models, Biological, Environmental Chemistry, Animals, Ecosystem, Parrotfish, Herbivory, Reef, General Environmental Science, El Nino-Southern Oscillation, Global and Planetary Change, geography, geography.geographical_feature_category, Ecology, Coral Reefs, Bioerosion, biology.organism_classification, Anthozoa, Belize, Perciformes, Oceanography

Abstract

As the frequency and intensity of coral mortality events increase under climate change, understanding how declines in coral cover may affect the bioerosion of reef frameworks is of increasing importance. Here, we explore decadal-scale rates of bioerosion of the framework building coral Orbicella annularis by grazing parrotfish following the 1997/1998 El Nino-related mass mortality event at Long Cay, Belize. Using high-precision U-Th dating and CT scan analysis, we quantified insitu rates of external bioerosion over a 13-year period (1998-2011). Based upon the error-weighted average U-Th age of dead O.annularis skeletons, we estimate the average external bioerosion between 1998 and 2011 as 0.92 +/- 0.55cm depth. Empirical observations of herbivore foraging, and a nonlinear numerical response of parrotfish to an increase in food availability, were used to create a model of external bioerosion at Long Cay. Model estimates of external bioerosion were in close agreement with U-Th estimates (0.85 +/- 0.09cm). The model was then used to quantify how rates of external bioerosion changed across a gradient of coral mortality (i.e., from few corals experiencing mortality following coral bleaching to complete mortality). Our results indicate that external bioerosion is remarkably robust to declines in coral cover, with no significant relationship predicted between the rate of external bioerosion and the proportion of O.annularis that died in the 1998 bleaching event. The outcome was robust because the reduction in grazing intensity that follows coral mortality was compensated for by a positive numerical response of parrotfish to an increase in food availability. Our model estimates further indicate that for an O.annularis-dominated reef to maintain a positive state of reef accretion, a necessity for sustained ecosystem function, live cover of O.annularis must not drop below a similar to 5-10% threshold of cover.

Published

2015

44. ENSO and NAO affect long-term leaf litter dynamics and stoichiometry of Scots pine and European beech mixedwoods.

Author

González de Andrés E, Blanco JA, Imbert JB, Guan BT, Lo YH, and Castillo FJ

Subjects

Ecosystem, El Nino-Southern Oscillation, Trees, Fagus, Pinus sylvestris

Abstract

Litterfall dynamics (production, seasonality and nutrient composition) are key factors influencing nutrient cycling. Leaf litter characteristics are modified by species composition, site conditions and water availability. However, significant evidence on how large-scale, global circulation patterns affect ecophysiological processes at tree and ecosystem level remains scarce due to the difficulty in separating the combined influence of different factors on local climate and tree phenology. To fill this gap, we studied links between leaf litter dynamics with climate and other forest processes, such as tree-ring width (TRW) and intrinsic water-use efficiency (iWUE) in two mixtures of Scots pine (Pinus sylvestris L.) and European beech (Fagus sylvatica L.) in the south-western Pyrenees. Temporal series (18 years) of litterfall production and elemental chemical composition were decomposed following the ensemble empirical mode decomposition method and relationships with local climate, large-scale climatic indices, TRW and Scots pine's iWUE were assessed. Temporal trends in N:P ratios indicated increasing P limitation of soil microbes, thus affecting nutrient availability, as the ecological succession from a pine-dominated to a beech-dominated forest took place. A significant influence of large-scale patterns on tree-level ecophysiology was explained through the impact of the North Atlantic Oscillation (NAO) and El Niño-Southern Oscillation (ENSO) on water availability. Positive NAO and negative ENSO were related to dry conditions and, consequently, to early needle shedding and increased N:P ratio of both species. Autumn storm activity appears to be related to premature leaf abscission of European beech. Significant cascading effects from large-scale patterns on local weather influenced pine TRW and iWUE. These variables also responded to leaf stoichiometry fallen 3 years prior to tree-ring formation. Our results provide evidence of the cascading effect that variability in global climate circulation patterns can have on ecophysiological processes and stand dynamics in mixed forests., (© 2019 John Wiley & Sons Ltd.)

Published

2019

45. Legacies of La Niña: North American monsoon can rescue trees from winter drought.

Author

Peltier DMP and Ogle K

Subjects

Climate Change, Environmental Monitoring, Rain, United States, Cyclonic Storms, Droughts, El Nino-Southern Oscillation, Seasons, Trees growth & development

Abstract

While we often assume tree growth-climate relationships are time-invariant, impacts of climate phenomena such as the El Niño Southern Oscillation (ENSO) and the North American Monsoon (NAM) may challenge this assumption. To test this assumption, we grouped ring widths (1900-present) in three southwestern US conifers into La Niña periods (LNP) and other years (OY). The 4 years following each La Niña year are included in LNP, and despite 1-2 year growth declines, compensatory adjustments in tree growth responses result in essentially equal mean growth in LNP and OY, as average growth exceeds OY means 2-4 years after La Niña events. We found this arises because growth responses in the two periods are not interchangeable: Due to differences in growth-climate sensitivities and climatic memory, parameters representing LNP growth fail to predict OY growth and vice versa (decreases in R 2 up to 0.63; lowest R 2  = 0.06). Temporal relationships between growth and antecedent climate (memory) show warmer springs and longer growing seasons negatively impact growth following dry La Niña winters, but that NAM moisture can rescue trees after these events. Increased importance of monsoonal precipitation during LNP is key, as the largest La Niña-related precipitation deficits and monsoonal precipitation contributions both occur in the southern part of the region. Decreases in first order autocorrelation during LNP were largest in the heart of the monsoon region, reflecting both the greatest initial growth declines and the largest recovery. Understanding the unique climatic controls on growth in Southwest conifers requires consideration of both the influences and interactions of drought, ENSO, and NAM, each of which is likely to change with continued warming. While plasticity of growth sensitivity and memory has allowed relatively quick recovery in the tree-ring record, recent widespread mortality events suggest conditions may soon exceed the capacity for adjustment in current populations., (© 2018 John Wiley & Sons Ltd.)

Published

2019

46. Linking El Niño, local rainfall, and migration timing in a tropical migratory species

Author

Kathryn A. Kelly and Allison K. Shaw

Subjects

El Nino-Southern Oscillation, Global and Planetary Change, Climate pattern, Ecology, biology, Brachyura, Phenology, Climate Change, Rain, Australia, Climate change, biology.organism_classification, Gecarcinidae, Geography, Effects of global warming, Temperate climate, Animals, Environmental Chemistry, Animal Migration, Climate model, sense organs, Precipitation, skin and connective tissue diseases, General Environmental Science

Abstract

Current climate models project changes in both temperature and precipitation patterns across the globe in the coming years. Migratory species, which move to take advantage of seasonal climate patterns, are likely to be affected by these changes, and indeed, a number of studies have shown a relationship between changing climate and the migration timing of various species. However, these studies have almost exclusively focused on the effects of temperature change on species that inhabit temperate zones. Here, we explore the relationship between rainfall and migration timing in a tropical species, Gecarcoidea natalis (Christmas Island red crab). We find that the timing of the annual crab breeding migration is closely related to the amount of rain that falls during a 'migration window' period prior to potential egg release dates, which is in turn related to the Southern Oscillation Index, an atmospheric El Niño-Southern Oscillation Index. As reproduction in this species is conditional on successful migration, major changes in migration patterns could have detrimental consequences for the survival of the species. This study serves to broaden our understanding of the effects of climate change on migratory species and will hopefully inspire future work on rainfall and tropical migrations.

Published

2013

47. Resilience of seed production to a severe El Niño-induced drought across functional groups and dispersal types.

Author

O'Brien MJ, Peréz-Aviles D, and Powers JS

Subjects

Reproduction, Trees, Tropical Climate, Wind, Droughts, El Nino-Southern Oscillation, Forests, Rain, Seeds

Abstract

More frequent and severe El Niño Southern Oscillations (ENSO) are causing episodic periods of decreased rainfall. Although the effects of these ENSO-induced droughts on tree growth and mortality have been well studied, the impacts on other demographic rates such as reproduction are less well known. We use a four-year seed rain dataset encompassing the most severe ENSO-induced drought in more than 30 years to assess the resilience (i.e., resistance and recovery) of the seed composition and abundance of three forest types in a tropical dry forest. We found that forest types showed distinct differences in the timing, duration, and intensity of drought during the ENSO event, which likely mediated seed composition shifts and resilience. Drought-deciduous species were particularly sensitive to the drought with overall poor resilience of seed production, whereby seed abundance of this functional group failed to recover to predrought levels even two years after the drought. Liana and wind-dispersed species were able to maintain seed production both during and after drought, suggesting that ENSO events promote early successional species or species with a colonization strategy. Combined, these results suggest that ENSO-induced drought mediates the establishment of functional groups and dispersal types suited for early successional conditions with more open canopies and reduced competition among plants. The effects of the ENSO-induced drought on seed composition and abundance were still evident two years after the event suggesting the recovery of seed production requires multiple years that may lead to shifts in forest composition and structure in the long term, with potential consequences for higher trophic levels like frugivores., (© 2018 John Wiley & Sons Ltd.)

Published

2018

48. The effects of El Niño-Southern Oscillation events on intertidal seagrass beds over a long-term timescale.

Author

Lin HJ, Lee CL, Peng SE, Hung MC, Liu PJ, and Mayfield AB

Subjects

Biomass, Ecosystem, Eutrophication, Nitrogen analysis, Plant Leaves, Seawater chemistry, El Nino-Southern Oscillation, Hydrocharitaceae physiology

Abstract

El Niño-Southern Oscillation (ENSO) events can cause dramatic changes in marine communities. However, we know little as to how ENSO events affect tropical seagrass beds over decadal timescales. Therefore, a diverse array of seagrass (Thalassia hemprichii) habitat types were surveyed once every 3 months for 16 years (January 2001 to February 2017) in a tropical intertidal zone that is regularly affected by both ENSO events and anthropogenic nutrient enrichment. La Niña and El Niño events had distinct effects on the biomass and growth of T. hemprichii. During La Niña years, higher (a) precipitation levels and (b) seawater nitrogen concentrations led to increases in seagrass leaf productivity, canopy height, and biomass. However, the latter simultaneously stimulated the growth of periphyton on seagrass leaves; this led to decreases in seagrass cover and shoot density. More frequent La Niña events could, then, eventually lead to either a decline in intertidal seagrass beds or a shift to another, less drought-resistant seagrass species in those regions already characterized by eutrophication due to local anthropogenic activity., (© 2018 John Wiley & Sons Ltd.)

Published

2018

49. Causes of reduced leaf-level photosynthesis during strong El Niño drought in a Central Amazon forest.

Author

Santos VAHFD, Ferreira MJ, Rodrigues JVFC, Garcia MN, Ceron JVB, Nelson BW, and Saleska SR

Subjects

Brazil, Plant Leaves physiology, Seasons, Droughts, El Nino-Southern Oscillation, Forests, Photosynthesis physiology, Trees physiology

Abstract

Sustained drought and concomitant high temperature may reduce photosynthesis and cause tree mortality. Possible causes of reduced photosynthesis include stomatal closure and biochemical inhibition, but their relative roles are unknown in Amazon trees during strong drought events. We assessed the effects of the recent (2015) strong El Niño drought on leaf-level photosynthesis of Central Amazon trees via these two mechanisms. Through four seasons of 2015, we measured leaf gas exchange, chlorophyll a fluorescence parameters, chlorophyll concentration, and nutrient content in leaves of 57 upper canopy and understory trees of a lowland terra firme forest on well-drained infertile oxisol. Photosynthesis decreased 28% in the upper canopy and 17% in understory trees during the extreme dry season of 2015, relative to other 2015 seasons and was also lower than the climatically normal dry season of the following non-El Niño year. Photosynthesis reduction under extreme drought and high temperature in the 2015 dry season was related only to stomatal closure in both upper canopy and understory trees, and not to chlorophyll a fluorescence parameters, chlorophyll, or leaf nutrient concentration. The distinction is important because stomatal closure is a transient regulatory response that can reverse when water becomes available, whereas the other responses reflect more permanent changes or damage to the photosynthetic apparatus. Photosynthesis decrease due to stomatal closure during the 2015 extreme dry season was followed 2 months later by an increase in photosynthesis as rains returned, indicating a margin of resilience to one-off extreme climatic events in Amazonian forests., (© 2018 John Wiley & Sons Ltd.)

Published

2018

50. Rising synchrony controls western North American ecosystems.

Author

Black BA, van der Sleen P, Di Lorenzo E, Griffin D, Sydeman WJ, Dunham JB, Rykaczewski RR, García-Reyes M, Safeeq M, Arismendi I, and Bograd SJ

Subjects

Environmental Monitoring, Rivers, Seasons, United States, Climate Change, Ecosystem, El Nino-Southern Oscillation

Abstract

Along the western margin of North America, the winter expression of the North Pacific High (NPH) strongly influences interannual variability in coastal upwelling, storm track position, precipitation, and river discharge. Coherence among these factors induces covariance among physical and biological processes across adjacent marine and terrestrial ecosystems. Here, we show that over the past century the degree and spatial extent of this covariance (synchrony) has substantially increased, and is coincident with rising variance in the winter NPH. Furthermore, centuries-long blue oak (Quercus douglasii) growth chronologies sensitive to the winter NPH provide robust evidence that modern levels of synchrony are among the highest observed in the context of the last 250 years. These trends may ultimately be linked to changing impacts of the El Niño Southern Oscillation on midlatitude ecosystems of North America. Such a rise in synchrony may destabilize ecosystems, expose populations to higher risks of extinction, and is thus a concern given the broad biological relevance of winter climate to biological systems., (© 2018 John Wiley & Sons Ltd.)

Published

2018