Contrasting carbon cycle responses to dry (2015 El Niño) and wet (2008 La Niña) extreme events at an Amazon tropical forest.

Contrasting carbon cycle responses to dry (2015 El Niño) and wet (2008 La Niña) extreme events at an Amazon tropical forest.

Land surface models diverge in their predictions of the Amazon forest's response to climate change-induced droughts, with some showing a catastrophic collapse of forests, while others simulating resilience. Therefore, observations of tropical ecosystem responses to real-world droughts and other extreme events are needed. We report long-term seasonal dynamics of photosynthesis, respiration, net carbon exchange, phenology, and tree demography and characterize the effect of dry and wet events on ecosystem form and function at the Tapajós National Forest, Brazil, using over two decades of eddy covariance observations that include the 2015–2016 El Niño drought and La Niña 2008–2009 wet periods. We found strong forest responses to both ENSO events: La Niña saw forest net carbon loss from reduced photosynthesis (due to lower incoming radiation from increased cloudiness) even as ecosystem respiration (Reco) was maintained at mean seasonal levels. El Niño induced the opposite short-term effect, net carbon gains, despite significant reductions in photosynthesis (from a drought-induced halving of canopy conductance to CO2 and significant losses of leaf area), because drought suppression of Reco losses was even greater. However, long-term responses to the two climate perturbations were very different: transient during La Niña –the forest returned to its “normal” state as soon as the climate did, and long-lasting during El Niño –leaf area loss and associated declines in photosynthetic capacity (Pc) and canopy conductance were exacerbated and extended by feedbacks from higher temperatures and atmospheric evaporative demand and persisted for ∼3+ years after normal rainfall resumed. These findings indicate that these forests are more vulnerable to drought than to excess rain, because drought drives significant changes in forest structure (e.g., leaf-abscission and mortality) and ecosystem function (e.g. reduced stomatal conductance). As future Amazonian climate change increases frequencies of hydrological extremes, these mechanisms will determine the long-term fate of tropical forests.

Saved in:
Bibliographic Details
Main Authors: RESTREPO-COUPE, N., CAMPOS, K. S., ALVES, L. F., LONGO, M., WIEDEMANN, K. T., OLIVEIRA JUNIOR, R. C. de, ARAGÃO, L. E., CHRISTOFFERSEN, B. O., CAMARGO, P. B., FIGUEIRA, A. M. S., FERREIRA, M. L., OLIVEIRA, R. S., PENHA, D., PROHASKA, N., ARAUJO, A. C. de, DAUBE, B. C., WOFSY, S. C., SALESKA, S. R.
Other Authors: NATALIA RESTREPO-COUPE, UNIVERSITY OF ARIZONA
Format: Artigo de periódico biblioteca
Language:eng
Published: 2024-06-06
Subjects:ENSO, Ecosystem-climate interactions, Water and energy flux seasonality, Eddy covariance, Carbon, Amazonia, Tropical forests,
Online Access:http://www.alice.cnptia.embrapa.br/alice/handle/doc/1164742
https://doi.org/10.1016/j.agrformet.2024.110037
Tags: Add Tag
No Tags, Be the first to tag this record!
id dig-alice-doc-1164742
record_format koha
spelling dig-alice-doc-11647422024-06-06T18:54:21Z Contrasting carbon cycle responses to dry (2015 El Niño) and wet (2008 La Niña) extreme events at an Amazon tropical forest. RESTREPO-COUPE, N. CAMPOS, K. S. ALVES, L. F. LONGO, M. WIEDEMANN, K. T. OLIVEIRA JUNIOR, R. C. de ARAGÃO, L. E. CHRISTOFFERSEN, B. O. CAMARGO, P. B. FIGUEIRA, A. M. S. FERREIRA, M. L. OLIVEIRA, R. S. PENHA, D. PROHASKA, N. ARAUJO, A. C. de DAUBE, B. C. WOFSY, S. C. SALESKA, S. R. NATALIA RESTREPO-COUPE, UNIVERSITY OF ARIZONA KLEBER SILVA CAMPOS, UNIVERSIDADE FEDERAL DO OESTE DO PARÁ LUCIANA F. ALVES, UNIVERSITY OF CALIFORNIA MARCOS LONGO, LAWRENCE BERKELEY NATIONAL LABORATORY KENIA T. WIEDEMANN, HARVARD UNIVERSITY RAIMUNDO COSME DE OLIVEIRA JUNIOR, CPATU LUIZ E. O. C. ARAGÃO, INSTITUTO NACIONAL DE PESQUISAS ESPACIAIS BRADLEY O. CHRISTOFFERSEN, UNIVERSITY OF TEXAS RIO GRANDE VALLEY PLINIO B. CAMARGO, UNIVERSIDADE DE SÃO PAULO ADELAINE M.E S. FIGUEIRA, UNIVERSIDADE FEDERAL DO OESTE DO PARÁ MAURÍCIO LAMANO FERREIRA, UNIVERSIDADE DE SÃO PAULO RAFAEL S. OLIVEIRA, UNIVERSIDADE ESTADUAL DE CAMPINAS DELIANE PENHA, UNIVERSIDADE FEDERAL DO OESTE DO PARÁ NEILL PROHASKA, UNIVERSITY OF ARIZONA ALESSANDRO CARIOCA DE ARAUJO, CPATU BRUCE C. DAUBE, HARVARD UNIVERSITY STEVEN C. WOFSY, HARVARD UNIVERSITY SCOTT R. SALESKA, UNIVERSITY OF ARIZONA. ENSO Ecosystem-climate interactions Water and energy flux seasonality Eddy covariance Carbon Amazonia Tropical forests Land surface models diverge in their predictions of the Amazon forest's response to climate change-induced droughts, with some showing a catastrophic collapse of forests, while others simulating resilience. Therefore, observations of tropical ecosystem responses to real-world droughts and other extreme events are needed. We report long-term seasonal dynamics of photosynthesis, respiration, net carbon exchange, phenology, and tree demography and characterize the effect of dry and wet events on ecosystem form and function at the Tapajós National Forest, Brazil, using over two decades of eddy covariance observations that include the 2015–2016 El Niño drought and La Niña 2008–2009 wet periods. We found strong forest responses to both ENSO events: La Niña saw forest net carbon loss from reduced photosynthesis (due to lower incoming radiation from increased cloudiness) even as ecosystem respiration (Reco) was maintained at mean seasonal levels. El Niño induced the opposite short-term effect, net carbon gains, despite significant reductions in photosynthesis (from a drought-induced halving of canopy conductance to CO2 and significant losses of leaf area), because drought suppression of Reco losses was even greater. However, long-term responses to the two climate perturbations were very different: transient during La Niña –the forest returned to its “normal” state as soon as the climate did, and long-lasting during El Niño –leaf area loss and associated declines in photosynthetic capacity (Pc) and canopy conductance were exacerbated and extended by feedbacks from higher temperatures and atmospheric evaporative demand and persisted for ∼3+ years after normal rainfall resumed. These findings indicate that these forests are more vulnerable to drought than to excess rain, because drought drives significant changes in forest structure (e.g., leaf-abscission and mortality) and ecosystem function (e.g. reduced stomatal conductance). As future Amazonian climate change increases frequencies of hydrological extremes, these mechanisms will determine the long-term fate of tropical forests. 2024-06-06T18:54:21Z 2024-06-06T18:54:21Z 2024-06-06 2024 Artigo de periódico Agricultural and Forest Meteorology, v. 353, 110037, 2024. http://www.alice.cnptia.embrapa.br/alice/handle/doc/1164742 https://doi.org/10.1016/j.agrformet.2024.110037 eng openAccess
institution EMBRAPA
collection DSpace
country Brasil
countrycode BR
component Bibliográfico
access En linea
databasecode dig-alice
tag biblioteca
region America del Sur
libraryname Sistema de bibliotecas de EMBRAPA
language eng
topic ENSO
Ecosystem-climate interactions
Water and energy flux seasonality
Eddy covariance
Carbon
Amazonia
Tropical forests
ENSO
Ecosystem-climate interactions
Water and energy flux seasonality
Eddy covariance
Carbon
Amazonia
Tropical forests
spellingShingle ENSO
Ecosystem-climate interactions
Water and energy flux seasonality
Eddy covariance
Carbon
Amazonia
Tropical forests
ENSO
Ecosystem-climate interactions
Water and energy flux seasonality
Eddy covariance
Carbon
Amazonia
Tropical forests
RESTREPO-COUPE, N.
CAMPOS, K. S.
ALVES, L. F.
LONGO, M.
WIEDEMANN, K. T.
OLIVEIRA JUNIOR, R. C. de
ARAGÃO, L. E.
CHRISTOFFERSEN, B. O.
CAMARGO, P. B.
FIGUEIRA, A. M. S.
FERREIRA, M. L.
OLIVEIRA, R. S.
PENHA, D.
PROHASKA, N.
ARAUJO, A. C. de
DAUBE, B. C.
WOFSY, S. C.
SALESKA, S. R.
Contrasting carbon cycle responses to dry (2015 El Niño) and wet (2008 La Niña) extreme events at an Amazon tropical forest.
description Land surface models diverge in their predictions of the Amazon forest's response to climate change-induced droughts, with some showing a catastrophic collapse of forests, while others simulating resilience. Therefore, observations of tropical ecosystem responses to real-world droughts and other extreme events are needed. We report long-term seasonal dynamics of photosynthesis, respiration, net carbon exchange, phenology, and tree demography and characterize the effect of dry and wet events on ecosystem form and function at the Tapajós National Forest, Brazil, using over two decades of eddy covariance observations that include the 2015–2016 El Niño drought and La Niña 2008–2009 wet periods. We found strong forest responses to both ENSO events: La Niña saw forest net carbon loss from reduced photosynthesis (due to lower incoming radiation from increased cloudiness) even as ecosystem respiration (Reco) was maintained at mean seasonal levels. El Niño induced the opposite short-term effect, net carbon gains, despite significant reductions in photosynthesis (from a drought-induced halving of canopy conductance to CO2 and significant losses of leaf area), because drought suppression of Reco losses was even greater. However, long-term responses to the two climate perturbations were very different: transient during La Niña –the forest returned to its “normal” state as soon as the climate did, and long-lasting during El Niño –leaf area loss and associated declines in photosynthetic capacity (Pc) and canopy conductance were exacerbated and extended by feedbacks from higher temperatures and atmospheric evaporative demand and persisted for ∼3+ years after normal rainfall resumed. These findings indicate that these forests are more vulnerable to drought than to excess rain, because drought drives significant changes in forest structure (e.g., leaf-abscission and mortality) and ecosystem function (e.g. reduced stomatal conductance). As future Amazonian climate change increases frequencies of hydrological extremes, these mechanisms will determine the long-term fate of tropical forests.
author2 NATALIA RESTREPO-COUPE, UNIVERSITY OF ARIZONA
author_facet NATALIA RESTREPO-COUPE, UNIVERSITY OF ARIZONA
RESTREPO-COUPE, N.
CAMPOS, K. S.
ALVES, L. F.
LONGO, M.
WIEDEMANN, K. T.
OLIVEIRA JUNIOR, R. C. de
ARAGÃO, L. E.
CHRISTOFFERSEN, B. O.
CAMARGO, P. B.
FIGUEIRA, A. M. S.
FERREIRA, M. L.
OLIVEIRA, R. S.
PENHA, D.
PROHASKA, N.
ARAUJO, A. C. de
DAUBE, B. C.
WOFSY, S. C.
SALESKA, S. R.
format Artigo de periódico
topic_facet ENSO
Ecosystem-climate interactions
Water and energy flux seasonality
Eddy covariance
Carbon
Amazonia
Tropical forests
author RESTREPO-COUPE, N.
CAMPOS, K. S.
ALVES, L. F.
LONGO, M.
WIEDEMANN, K. T.
OLIVEIRA JUNIOR, R. C. de
ARAGÃO, L. E.
CHRISTOFFERSEN, B. O.
CAMARGO, P. B.
FIGUEIRA, A. M. S.
FERREIRA, M. L.
OLIVEIRA, R. S.
PENHA, D.
PROHASKA, N.
ARAUJO, A. C. de
DAUBE, B. C.
WOFSY, S. C.
SALESKA, S. R.
author_sort RESTREPO-COUPE, N.
title Contrasting carbon cycle responses to dry (2015 El Niño) and wet (2008 La Niña) extreme events at an Amazon tropical forest.
title_short Contrasting carbon cycle responses to dry (2015 El Niño) and wet (2008 La Niña) extreme events at an Amazon tropical forest.
title_full Contrasting carbon cycle responses to dry (2015 El Niño) and wet (2008 La Niña) extreme events at an Amazon tropical forest.
title_fullStr Contrasting carbon cycle responses to dry (2015 El Niño) and wet (2008 La Niña) extreme events at an Amazon tropical forest.
title_full_unstemmed Contrasting carbon cycle responses to dry (2015 El Niño) and wet (2008 La Niña) extreme events at an Amazon tropical forest.
title_sort contrasting carbon cycle responses to dry (2015 el niño) and wet (2008 la niña) extreme events at an amazon tropical forest.
publishDate 2024-06-06
url http://www.alice.cnptia.embrapa.br/alice/handle/doc/1164742
https://doi.org/10.1016/j.agrformet.2024.110037
work_keys_str_mv AT restrepocoupen contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT camposks contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT alveslf contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT longom contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT wiedemannkt contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT oliveirajuniorrcde contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT aragaole contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT christoffersenbo contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT camargopb contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT figueiraams contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT ferreiraml contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT oliveirars contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT penhad contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT prohaskan contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT araujoacde contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT daubebc contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT wofsysc contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
AT saleskasr contrastingcarboncycleresponsestodry2015elninoandwet2008laninaextremeeventsatanamazontropicalforest
_version_ 1802818279868203008

Similar Items