Satellite observed aboveground carbon dynamics in Africa during 2003–2021

Research output: Contribution to journalJournal articleResearchpeer-review

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Satellite observed aboveground carbon dynamics in Africa during 2003–2021. / Wang, Mengjia; Ciais, Philippe; Fensholt, Rasmus; Brandt, Martin; Tao, Shengli; Li, Wei; Fan, Lei; Frappart, Frédéric; Sun, Rui; Li, Xiaojun; Liu, Xiangzhuo; Wang, Huan; Cui, Tianxiang; Xing, Zanpin; Zhao, Zhe; Wigneron, Jean Pierre.

In: Remote Sensing of Environment, Vol. 301, 113927, 2024.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Wang, M, Ciais, P, Fensholt, R, Brandt, M, Tao, S, Li, W, Fan, L, Frappart, F, Sun, R, Li, X, Liu, X, Wang, H, Cui, T, Xing, Z, Zhao, Z & Wigneron, JP 2024, 'Satellite observed aboveground carbon dynamics in Africa during 2003–2021', Remote Sensing of Environment, vol. 301, 113927. https://doi.org/10.1016/j.rse.2023.113927

APA

Wang, M., Ciais, P., Fensholt, R., Brandt, M., Tao, S., Li, W., Fan, L., Frappart, F., Sun, R., Li, X., Liu, X., Wang, H., Cui, T., Xing, Z., Zhao, Z., & Wigneron, J. P. (2024). Satellite observed aboveground carbon dynamics in Africa during 2003–2021. Remote Sensing of Environment, 301, [113927]. https://doi.org/10.1016/j.rse.2023.113927

Vancouver

Wang M, Ciais P, Fensholt R, Brandt M, Tao S, Li W et al. Satellite observed aboveground carbon dynamics in Africa during 2003–2021. Remote Sensing of Environment. 2024;301. 113927. https://doi.org/10.1016/j.rse.2023.113927

Author

Wang, Mengjia ; Ciais, Philippe ; Fensholt, Rasmus ; Brandt, Martin ; Tao, Shengli ; Li, Wei ; Fan, Lei ; Frappart, Frédéric ; Sun, Rui ; Li, Xiaojun ; Liu, Xiangzhuo ; Wang, Huan ; Cui, Tianxiang ; Xing, Zanpin ; Zhao, Zhe ; Wigneron, Jean Pierre. / Satellite observed aboveground carbon dynamics in Africa during 2003–2021. In: Remote Sensing of Environment. 2024 ; Vol. 301.

Bibtex

@article{2cba7a59c9224115aa576ca849e1bceb,
title = "Satellite observed aboveground carbon dynamics in Africa during 2003–2021",
abstract = "Vegetation dynamics in the African continent play an important role in the global terrestrial carbon cycle. Above-ground biomass carbon (AGC) stocks in Africa are sensitive to drought, fires and anthropogenic disturbances, and can be increased from forest restoration and tree plantation. However, there are large uncertainties in estimating changes that have occurred in AGC stocks in Africa over the past decades. Here, we used a microwave remote sensing-based vegetation index named Vegetation Optical Depth produced from X-band observations by INRAE Bordeaux (IB X-VOD) to describe the AGC dynamics in Africa covering recent decades. From 2003 to 2021, African AGC showed a net increase at a rate of +0.06 [+0.04, +0.07] PgC·yr−1 (the range represents the minimum and maximum AGC changes estimated by four calibrations), resulting from a large carbon gain of +0.55 [+0.46, +0.60] PgC·yr−1 during the first decade of the twenty-first century (period 1: 2003–2010) and a much weaker increase of +0.05 [+0.04, +0.07] PgC·yr−1 over the recent decade (period 2: 2013–2021). AGC gains were mainly found in non-forest woody areas, which contributed the most to the AGC changes during 2003–2021. Rainforests showed a minor AGC loss of −0.02 [−0.03, −0.02] PgC·yr−1, which emphasizes the need for forest conservation in Africa. Relationships between the AGC changes and potential forcing climate or anthropogenic variables suggested that human-induced deforestation and water stress (especially the vapor pressure deficit (VPD)) are the most important variables explaining the spatial and temporal AGC variations, respectively. For areas of rainforests, we identified a strong relationship between AGC and VPD (negative), soil moisture (positive) and radiation (positive). For areas of sparse vegetation (mainly located in drylands), AGC changes are largely dominated by changes in the soil water conditions. This study presents a new dataset for monitoring AGC dynamics at a continental scale over recent decades being independent of optical observations, quantifying the impacts of anthropogenic pressure and water stress on aboveground biomass carbon changes.",
keywords = "Aboveground carbon dynamics, African continent, Vegetation optical depth",
author = "Mengjia Wang and Philippe Ciais and Rasmus Fensholt and Martin Brandt and Shengli Tao and Wei Li and Lei Fan and Fr{\'e}d{\'e}ric Frappart and Rui Sun and Xiaojun Li and Xiangzhuo Liu and Huan Wang and Tianxiang Cui and Zanpin Xing and Zhe Zhao and Wigneron, {Jean Pierre}",
note = "Publisher Copyright: {\textcopyright} 2023 Elsevier Inc.",
year = "2024",
doi = "10.1016/j.rse.2023.113927",
language = "English",
volume = "301",
journal = "Remote Sensing of Environment",
issn = "0034-4257",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Satellite observed aboveground carbon dynamics in Africa during 2003–2021

AU - Wang, Mengjia

AU - Ciais, Philippe

AU - Fensholt, Rasmus

AU - Brandt, Martin

AU - Tao, Shengli

AU - Li, Wei

AU - Fan, Lei

AU - Frappart, Frédéric

AU - Sun, Rui

AU - Li, Xiaojun

AU - Liu, Xiangzhuo

AU - Wang, Huan

AU - Cui, Tianxiang

AU - Xing, Zanpin

AU - Zhao, Zhe

AU - Wigneron, Jean Pierre

N1 - Publisher Copyright: © 2023 Elsevier Inc.

PY - 2024

Y1 - 2024

N2 - Vegetation dynamics in the African continent play an important role in the global terrestrial carbon cycle. Above-ground biomass carbon (AGC) stocks in Africa are sensitive to drought, fires and anthropogenic disturbances, and can be increased from forest restoration and tree plantation. However, there are large uncertainties in estimating changes that have occurred in AGC stocks in Africa over the past decades. Here, we used a microwave remote sensing-based vegetation index named Vegetation Optical Depth produced from X-band observations by INRAE Bordeaux (IB X-VOD) to describe the AGC dynamics in Africa covering recent decades. From 2003 to 2021, African AGC showed a net increase at a rate of +0.06 [+0.04, +0.07] PgC·yr−1 (the range represents the minimum and maximum AGC changes estimated by four calibrations), resulting from a large carbon gain of +0.55 [+0.46, +0.60] PgC·yr−1 during the first decade of the twenty-first century (period 1: 2003–2010) and a much weaker increase of +0.05 [+0.04, +0.07] PgC·yr−1 over the recent decade (period 2: 2013–2021). AGC gains were mainly found in non-forest woody areas, which contributed the most to the AGC changes during 2003–2021. Rainforests showed a minor AGC loss of −0.02 [−0.03, −0.02] PgC·yr−1, which emphasizes the need for forest conservation in Africa. Relationships between the AGC changes and potential forcing climate or anthropogenic variables suggested that human-induced deforestation and water stress (especially the vapor pressure deficit (VPD)) are the most important variables explaining the spatial and temporal AGC variations, respectively. For areas of rainforests, we identified a strong relationship between AGC and VPD (negative), soil moisture (positive) and radiation (positive). For areas of sparse vegetation (mainly located in drylands), AGC changes are largely dominated by changes in the soil water conditions. This study presents a new dataset for monitoring AGC dynamics at a continental scale over recent decades being independent of optical observations, quantifying the impacts of anthropogenic pressure and water stress on aboveground biomass carbon changes.

AB - Vegetation dynamics in the African continent play an important role in the global terrestrial carbon cycle. Above-ground biomass carbon (AGC) stocks in Africa are sensitive to drought, fires and anthropogenic disturbances, and can be increased from forest restoration and tree plantation. However, there are large uncertainties in estimating changes that have occurred in AGC stocks in Africa over the past decades. Here, we used a microwave remote sensing-based vegetation index named Vegetation Optical Depth produced from X-band observations by INRAE Bordeaux (IB X-VOD) to describe the AGC dynamics in Africa covering recent decades. From 2003 to 2021, African AGC showed a net increase at a rate of +0.06 [+0.04, +0.07] PgC·yr−1 (the range represents the minimum and maximum AGC changes estimated by four calibrations), resulting from a large carbon gain of +0.55 [+0.46, +0.60] PgC·yr−1 during the first decade of the twenty-first century (period 1: 2003–2010) and a much weaker increase of +0.05 [+0.04, +0.07] PgC·yr−1 over the recent decade (period 2: 2013–2021). AGC gains were mainly found in non-forest woody areas, which contributed the most to the AGC changes during 2003–2021. Rainforests showed a minor AGC loss of −0.02 [−0.03, −0.02] PgC·yr−1, which emphasizes the need for forest conservation in Africa. Relationships between the AGC changes and potential forcing climate or anthropogenic variables suggested that human-induced deforestation and water stress (especially the vapor pressure deficit (VPD)) are the most important variables explaining the spatial and temporal AGC variations, respectively. For areas of rainforests, we identified a strong relationship between AGC and VPD (negative), soil moisture (positive) and radiation (positive). For areas of sparse vegetation (mainly located in drylands), AGC changes are largely dominated by changes in the soil water conditions. This study presents a new dataset for monitoring AGC dynamics at a continental scale over recent decades being independent of optical observations, quantifying the impacts of anthropogenic pressure and water stress on aboveground biomass carbon changes.

KW - Aboveground carbon dynamics

KW - African continent

KW - Vegetation optical depth

U2 - 10.1016/j.rse.2023.113927

DO - 10.1016/j.rse.2023.113927

M3 - Journal article

AN - SCOPUS:85178115626

VL - 301

JO - Remote Sensing of Environment

JF - Remote Sensing of Environment

SN - 0034-4257

M1 - 113927

ER -

ID: 382437995