Future Carbon Emissions from Global Mangrove Forest Loss

Overview

Journal Glob Chang Biol

Specialties Biology
Environmental Health

Date 2021 Mar 1

PMID 33644947

Citations 12

Authors

Maria F Adame

Rod M Connolly

Mischa P Turschwell

Catherine E Lovelock

Temilola Fatoyinbo

David Lagomasino

Liza A Goldberg

Jordan Holdorf

Daniel A Friess

Sigit D Sasmito

Jonathan Sanderman

Michael Sievers

Christina Buelow

J Boone Kauffman

Dale Bryan-Brown

Christopher J Brown

Affiliations

Soon will be listed here.

Abstract

Mangroves have among the highest carbon densities of any tropical forest. These 'blue carbon' ecosystems can store large amounts of carbon for long periods, and their protection reduces greenhouse gas emissions and supports climate change mitigation. Incorporating mangroves into Nationally Determined Contributions to the Paris Agreement and their valuation on carbon markets requires predicting how the management of different land-uses can prevent future greenhouse gas emissions and increase CO sequestration. We integrated comprehensive global datasets for carbon stocks, mangrove distribution, deforestation rates, and land-use change drivers into a predictive model of mangrove carbon emissions. We project emissions and foregone soil carbon sequestration potential under 'business as usual' rates of mangrove loss. Emissions from mangrove loss could reach 2391 Tg CO by the end of the century, or 3392 Tg CO when considering foregone soil carbon sequestration. The highest emissions were predicted in southeast and south Asia (West Coral Triangle, Sunda Shelf, and the Bay of Bengal) due to conversion to aquaculture or agriculture, followed by the Caribbean (Tropical Northwest Atlantic) due to clearing and erosion, and the Andaman coast (West Myanmar) and north Brazil due to erosion. Together, these six regions accounted for 90% of the total potential CO future emissions. Mangrove loss has been slowing, and global emissions could be more than halved if reduced loss rates remain in the future. Notably, the location of global emission hotspots was consistent with every dataset used to calculate deforestation rates or with alternative assumptions about carbon storage and emissions. Our results indicate the regions in need of policy actions to address emissions arising from mangrove loss and the drivers that could be managed to prevent them.

Citing Articles

Half of land use carbon emissions in Southeast Asia can be mitigated through peat swamp forest and mangrove conservation and restoration.

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A New Global Mangrove Height Map with a 12 meter spatial resolution.

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Exotic mangrove litter input accelerates nutrient cycling in mangrove ecosystems.

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Guo M, Yang L, Zhang L, Shen F, Meadows M, Zhou C Environ Sci Ecotechnol. 2024; 23:100482.

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