Resilience to Hurricanes Is High in Mangrove Blue Carbon Forests

ABSTRACT Mangrove forests are typically considered resilient to natural disturbances, likely caused by the evolutionary adaptation of species‐specific traits. These ecosystems play a vital role in the global carbon cycle and are responsible for an outsized contribution to carbon burial and enhanced...

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Published inGlobal change biology Vol. 31; no. 3; pp. e70124 - n/a
Main Authors Reed, David, Chavez, Selena, Castañeda‐Moya, Edward, Oberbauer, Steven F., Troxler, Tiffany, Malone, Sparkle
Format Journal Article
LanguageEnglish
Published England Blackwell Publishing Ltd 01.03.2025
John Wiley and Sons Inc
Subjects
Blue carbon
canopy
Carbon
Carbon Cycle
carbon cycling
Carbon dioxide
Carbon sinks
Cyclonic Storms
debt
Ecological adaptation
Ecosystem disturbance
Ecosystem recovery
ecosystem respiration
Ecosystem structure
Ecosystems
eddy covariance
evolutionary adaptation
Florida
Forests
global carbon budget
global change
Hurricanes
landscapes
Leaf area
Leaf area index
mangrove
mangrove forests
Mangrove swamps
Mangroves
Natural disturbance
net ecosystem exchange
Photosynthesis
Recovery
Resilience
Sedimentation rates
shrublands
Storms
Structure-function relationships
Tropical forests
Wetlands
Florida
Everglades
carbon cycling
mangrove
ecosystem disturbance
eddy covariance
ecosystem recovery
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Summary:ABSTRACT Mangrove forests are typically considered resilient to natural disturbances, likely caused by the evolutionary adaptation of species‐specific traits. These ecosystems play a vital role in the global carbon cycle and are responsible for an outsized contribution to carbon burial and enhanced sedimentation rates. Using eddy covariance data from two coastal mangrove forests in the Florida Coastal Everglades, we evaluated the impact hurricanes have on mangrove forest structure and function by measuring recovery to pre‐disturbance conditions following Hurricane Wilma in 2005 and Hurricane Irma in 2017. We determined the “recovery debt,” the deficit in ecosystem structure and function following a disturbance, using the leaf area index (LAI) and the net ecosystem exchange (NEE) of carbon dioxide (CO2). Calculated as the cumulative deviation from pre‐disturbance conditions, the recovery debt incorporated the recapture of all the carbon lost due to the disturbance. In Everglades mangrove forests, LAI returned to pre‐disturbance levels within a year, and ecosystem respiration and maximum photosynthetic rates took much longer, resulting in an initial recovery debt of 178 g C m−2 at the tall forest with limited impacts at the scrub forest. At the landscape scale, the initial recovery debt was 0.40 Mt C, and in most coastal mangrove forests, all lost carbon was recovered within just 4 years. While high‐intensity storms could have prolonged impacts on the structure of subtropical forests, fast canopy recovery suggests these ecosystems will remain strong carbon sinks. Mangrove forests are an important part of global carbon cycling and are also subject to disturbances from large storms. While initial carbon losses are high following hurricane landfalls, in this work we show that these forests recover to their baseline conditions within 4 years.
Bibliography:This research was supported by Everglades National Park (Cooperative Agreement No. P16AC00032 Task Agreement No. P17AC01282), The National Science Foundation (NSF) (Award Numbers 2047687, 2330792, and 1561161), the Yale School of the Environment, and the Yale Center for Natural Carbon Capture. The Florida Coastal Everglades Long‐Term Ecological Research (FCE‐LTER) program was supported through NSF grants: DEB‐9910514, DBI‐0620409, DEB‐1237517, DEB‐1832229, and DEB‐2025954. The U.S. Department of Energy Office of Science funded the AmeriFlux data portal. We thank Rafael Diaz‐Hung, Lukas Lamb‐Wotton, and Rafael Travieso for their field assistance in data collection, tower construction, and maintenance. Thanks to the Everglades National Park for granting research permits and the Florida Bay Interagency Science Center –Everglades National Park (FBISC‐ENP) for logistic support during the study. David Reed would especially like to thank Y. Reed for 15 years of support. This is contribution number #1828 from the Institute of Environment at Florida International University.
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Funding: This research was supported by Everglades National Park (Cooperative Agreement No. P16AC00032 Task Agreement No. P17AC01282), The National Science Foundation (NSF) (Award Numbers 2047687, 2330792, and 1561161), the Yale School of the Environment, and the Yale Center for Natural Carbon Capture. The Florida Coastal Everglades Long‐Term Ecological Research (FCE‐LTER) program was supported through NSF grants: DEB‐9910514, DBI‐0620409, DEB‐1237517, DEB‐1832229, and DEB‐2025954. The U.S. Department of Energy Office of Science funded the AmeriFlux data portal. We thank Rafael Diaz‐Hung, Lukas Lamb‐Wotton, and Rafael Travieso for their field assistance in data collection, tower construction, and maintenance. Thanks to the Everglades National Park for granting research permits and the Florida Bay Interagency Science Center –Everglades National Park (FBISC‐ENP) for logistic support during the study. David Reed would especially like to thank Y. Reed for 15 years of support. This is contribution number #1828 from the Institute of Environment at Florida International University.
ISSN:1354-1013
1365-2486
1365-2486
DOI:10.1111/gcb.70124