Past decade above-ground biomass change comparisons from four multi-temporal global maps

Arnan Araza; Martin Herold; Sytze de Bruin; Philippe Ciais; David A. Gibbs; Nancy Harris; Maurizio Santoro; Jean Pierre Wigneron; Hui Yang; Natalia Málaga; Karimon Nesha; Pedro Rodriguez-Veiga; Olga Brovkina; Hugh C.A. Brown; Milen Chanev; Zlatomir Dimitrov; Lachezar Filchev; Jonas Fridman; Mariano García; Alexander Gikov; Leen Govaere; Petar Dimitrov; Fardin Moradi; Adriane Esquivel Muelbert; Jan Novotný; Thomas A.M. Pugh; Mart Jan Schelhaas; Dmitry Schepaschenko; Krzysztof Stereńczak; Lars Hein

doi:10.1016/j.jag.2023.103274

Past decade above-ground biomass change comparisons from four multi-temporal global maps

Arnan Araza^*, Martin Herold, Sytze de Bruin, Philippe Ciais, David A. Gibbs, Nancy Harris, Maurizio Santoro, Jean Pierre Wigneron, Hui Yang, Natalia Málaga, Karimon Nesha, Pedro Rodriguez-Veiga, Olga Brovkina, Hugh C.A. Brown, Milen Chanev, Zlatomir Dimitrov, Lachezar Filchev, Jonas Fridman, Mariano García, Alexander GikovLeen Govaere, Petar Dimitrov, Fardin Moradi, Adriane Esquivel Muelbert, Jan Novotný, Thomas A.M. Pugh, Mart Jan Schelhaas, Dmitry Schepaschenko, Krzysztof Stereńczak, Lars Hein

^*Corresponding author for this work

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Abstract

Above-ground biomass (AGB) is considered an essential climate variable that underpins our knowledge and information about the role of forests in mitigating climate change. The availability of satellite-based AGB and AGB change (ΔAGB) products has increased in recent years. Here we assessed the past decade net ΔAGB derived from four recent global multi-date AGB maps: ESA-CCI maps, WRI-Flux model, JPL time series, and SMOS-LVOD time series. Our assessments explore and use different reference data sources with biomass re-measurements within the past decade. The reference data comprise National Forest Inventory (NFI) plot data, local ΔAGB maps from airborne LiDAR, and selected Forest Resource Assessment country data from countries with well-developed monitoring capacities. Map to reference data comparisons were performed at levels ranging from 100 m to 25 km spatial scale. The comparisons revealed that LiDAR data compared most reasonably with the maps, while the comparisons using NFI only showed some agreements at aggregation levels <10 km. Regardless of the aggregation level, AGB losses and gains according to the map comparisons were consistently smaller than the reference data. Map-map comparisons at 25 km highlighted that the maps consistently captured AGB losses in known deforestation hotspots. The comparisons also identified several carbon sink regions consistently detected by all maps. However, disagreement between maps is still large in key forest regions such as the Amazon basin. The overall ΔAGB map cross-correlation between maps varied in the range 0.11–0.29 (r). Reported ΔAGB magnitudes were largest in the high-resolution datasets including the CCI map differencing (stock change) and Flux model (gain-loss) methods, while they were smallest according to the coarser-resolution LVOD and JPL time series products, especially for AGB gains. Our results suggest that ΔAGB assessed from current maps can be biased and any use of the estimates should take that into account. Currently, ΔAGB reference data are sparse especially in the tropics but that deficit can be alleviated by upcoming LiDAR data networks in the context of Supersites and GEO-Trees.

Original language	English
Article number	103274
Number of pages	12
Journal	International Journal of Applied Earth Observation and Geoinformation
Volume	118
DOIs	https://doi.org/10.1016/j.jag.2023.103274
Publication status	Published - 4 Apr 2023

Bibliographical note

Funding Information:
This study was partly supported by the (1) IFBN/FOS (contract no. 4000114425/15/NL/FF/gp), SEN4LDN and CCI Biomass (contract no. 4000123662/18/I-NB) projects funded by the European Space Agency; (2) VERIFY Project: Observation-based system for monitoring and verification of greenhouse gases (GA number 776810, RIA). Acknowledgement is also given to the Open Earth Monitor Project from European Union's Horizon Europe research an innovation programme (grant agreement 101059548); the World Resources Institute (WRI) land and carbon lab support to WUR and GFZ; and the CGIAT MITIGATE+ project. Authors TAMP, AEM and MJS acknowledge funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement no. 758873, TreeMort). This study contributes to the Strategic Research Areas BECC and MERGE. Czech Republic data was supported by the Ministry of Education, Youth and Sports of the Czech Republic within the CzeCOS program, grant number LM2023048. Polish data was supported by Project LIFE+ ForBioSensing (contract number LIFE13 ENV/PL/000048) and Poland's National Fund for Environmental Protection and Water Management (contract number 485/2014/WN10/OP-NMLF/D). We sincerely thank Nicolas Labriere for processing and providing the LiDAR reference data. We also thank Maciej Lisiewicz and Lukasz Kuberski, for their assistance in Polish data preparation.

Publisher Copyright:
© 2023 The Author(s)

Keywords

Above-ground biomass
Above-ground biomass change
Carbon flux
Earth observation
Global carbon cycle
Map assessment

ASJC Scopus subject areas

Global and Planetary Change
Earth-Surface Processes
Computers in Earth Sciences
Management, Monitoring, Policy and Law

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1016/j.jag.2023.103274Licence: Creative Commons: Attribution (CC BY)

ArazaA2023PastFinal published version, 3.25 MBLicence: Creative Commons: Attribution (CC BY)

H2020_ERC_TREEMORT
Pugh, T.
European Commission
1/02/18 → 31/07/23
Project: EU

Cite this

Araza, A., Herold, M., de Bruin, S., Ciais, P., Gibbs, D. A., Harris, N., Santoro, M., Wigneron, J. P., Yang, H., Málaga, N., Nesha, K., Rodriguez-Veiga, P., Brovkina, O., Brown, H. C. A., Chanev, M., Dimitrov, Z., Filchev, L., Fridman, J., García, M., ... Hein, L. (2023). Past decade above-ground biomass change comparisons from four multi-temporal global maps. International Journal of Applied Earth Observation and Geoinformation, 118, Article 103274. https://doi.org/10.1016/j.jag.2023.103274

@article{61b895d67ffb4072ac399b9f17093820,

title = "Past decade above-ground biomass change comparisons from four multi-temporal global maps",

abstract = "Above-ground biomass (AGB) is considered an essential climate variable that underpins our knowledge and information about the role of forests in mitigating climate change. The availability of satellite-based AGB and AGB change (ΔAGB) products has increased in recent years. Here we assessed the past decade net ΔAGB derived from four recent global multi-date AGB maps: ESA-CCI maps, WRI-Flux model, JPL time series, and SMOS-LVOD time series. Our assessments explore and use different reference data sources with biomass re-measurements within the past decade. The reference data comprise National Forest Inventory (NFI) plot data, local ΔAGB maps from airborne LiDAR, and selected Forest Resource Assessment country data from countries with well-developed monitoring capacities. Map to reference data comparisons were performed at levels ranging from 100 m to 25 km spatial scale. The comparisons revealed that LiDAR data compared most reasonably with the maps, while the comparisons using NFI only showed some agreements at aggregation levels <10 km. Regardless of the aggregation level, AGB losses and gains according to the map comparisons were consistently smaller than the reference data. Map-map comparisons at 25 km highlighted that the maps consistently captured AGB losses in known deforestation hotspots. The comparisons also identified several carbon sink regions consistently detected by all maps. However, disagreement between maps is still large in key forest regions such as the Amazon basin. The overall ΔAGB map cross-correlation between maps varied in the range 0.11–0.29 (r). Reported ΔAGB magnitudes were largest in the high-resolution datasets including the CCI map differencing (stock change) and Flux model (gain-loss) methods, while they were smallest according to the coarser-resolution LVOD and JPL time series products, especially for AGB gains. Our results suggest that ΔAGB assessed from current maps can be biased and any use of the estimates should take that into account. Currently, ΔAGB reference data are sparse especially in the tropics but that deficit can be alleviated by upcoming LiDAR data networks in the context of Supersites and GEO-Trees.",

keywords = "Above-ground biomass, Above-ground biomass change, Carbon flux, Earth observation, Global carbon cycle, Map assessment",

author = "Arnan Araza and Martin Herold and {de Bruin}, Sytze and Philippe Ciais and Gibbs, {David A.} and Nancy Harris and Maurizio Santoro and Wigneron, {Jean Pierre} and Hui Yang and Natalia M{\'a}laga and Karimon Nesha and Pedro Rodriguez-Veiga and Olga Brovkina and Brown, {Hugh C.A.} and Milen Chanev and Zlatomir Dimitrov and Lachezar Filchev and Jonas Fridman and Mariano Garc{\'i}a and Alexander Gikov and Leen Govaere and Petar Dimitrov and Fardin Moradi and Muelbert, {Adriane Esquivel} and Jan Novotn{\'y} and Pugh, {Thomas A.M.} and Schelhaas, {Mart Jan} and Dmitry Schepaschenko and Krzysztof Stere{\'n}czak and Lars Hein",

note = "Funding Information: This study was partly supported by the (1) IFBN/FOS (contract no. 4000114425/15/NL/FF/gp), SEN4LDN and CCI Biomass (contract no. 4000123662/18/I-NB) projects funded by the European Space Agency; (2) VERIFY Project: Observation-based system for monitoring and verification of greenhouse gases (GA number 776810, RIA). Acknowledgement is also given to the Open Earth Monitor Project from European Union's Horizon Europe research an innovation programme (grant agreement 101059548); the World Resources Institute (WRI) land and carbon lab support to WUR and GFZ; and the CGIAT MITIGATE+ project. Authors TAMP, AEM and MJS acknowledge funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement no. 758873, TreeMort). This study contributes to the Strategic Research Areas BECC and MERGE. Czech Republic data was supported by the Ministry of Education, Youth and Sports of the Czech Republic within the CzeCOS program, grant number LM2023048. Polish data was supported by Project LIFE+ ForBioSensing (contract number LIFE13 ENV/PL/000048) and Poland's National Fund for Environmental Protection and Water Management (contract number 485/2014/WN10/OP-NMLF/D). We sincerely thank Nicolas Labriere for processing and providing the LiDAR reference data. We also thank Maciej Lisiewicz and Lukasz Kuberski, for their assistance in Polish data preparation. Publisher Copyright: {\textcopyright} 2023 The Author(s)",

year = "2023",

month = apr,

day = "4",

doi = "10.1016/j.jag.2023.103274",

language = "English",

volume = "118",

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Araza, A, Herold, M, de Bruin, S, Ciais, P, Gibbs, DA, Harris, N, Santoro, M, Wigneron, JP, Yang, H, Málaga, N, Nesha, K, Rodriguez-Veiga, P, Brovkina, O, Brown, HCA, Chanev, M, Dimitrov, Z, Filchev, L, Fridman, J, García, M, Gikov, A, Govaere, L, Dimitrov, P, Moradi, F, Muelbert, AE, Novotný, J, Pugh, TAM, Schelhaas, MJ, Schepaschenko, D, Stereńczak, K & Hein, L 2023, 'Past decade above-ground biomass change comparisons from four multi-temporal global maps', International Journal of Applied Earth Observation and Geoinformation, vol. 118, 103274. https://doi.org/10.1016/j.jag.2023.103274

TY - JOUR

T1 - Past decade above-ground biomass change comparisons from four multi-temporal global maps

AU - Araza, Arnan

AU - Herold, Martin

AU - de Bruin, Sytze

AU - Ciais, Philippe

AU - Gibbs, David A.

AU - Harris, Nancy

AU - Santoro, Maurizio

AU - Wigneron, Jean Pierre

AU - Yang, Hui

AU - Málaga, Natalia

AU - Nesha, Karimon

AU - Rodriguez-Veiga, Pedro

AU - Brovkina, Olga

AU - Brown, Hugh C.A.

AU - Chanev, Milen

AU - Dimitrov, Zlatomir

AU - Filchev, Lachezar

AU - Fridman, Jonas

AU - García, Mariano

AU - Gikov, Alexander

AU - Govaere, Leen

AU - Dimitrov, Petar

AU - Moradi, Fardin

AU - Muelbert, Adriane Esquivel

AU - Novotný, Jan

AU - Pugh, Thomas A.M.

AU - Schelhaas, Mart Jan

AU - Schepaschenko, Dmitry

AU - Stereńczak, Krzysztof

AU - Hein, Lars

N1 - Funding Information: This study was partly supported by the (1) IFBN/FOS (contract no. 4000114425/15/NL/FF/gp), SEN4LDN and CCI Biomass (contract no. 4000123662/18/I-NB) projects funded by the European Space Agency; (2) VERIFY Project: Observation-based system for monitoring and verification of greenhouse gases (GA number 776810, RIA). Acknowledgement is also given to the Open Earth Monitor Project from European Union's Horizon Europe research an innovation programme (grant agreement 101059548); the World Resources Institute (WRI) land and carbon lab support to WUR and GFZ; and the CGIAT MITIGATE+ project. Authors TAMP, AEM and MJS acknowledge funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement no. 758873, TreeMort). This study contributes to the Strategic Research Areas BECC and MERGE. Czech Republic data was supported by the Ministry of Education, Youth and Sports of the Czech Republic within the CzeCOS program, grant number LM2023048. Polish data was supported by Project LIFE+ ForBioSensing (contract number LIFE13 ENV/PL/000048) and Poland's National Fund for Environmental Protection and Water Management (contract number 485/2014/WN10/OP-NMLF/D). We sincerely thank Nicolas Labriere for processing and providing the LiDAR reference data. We also thank Maciej Lisiewicz and Lukasz Kuberski, for their assistance in Polish data preparation. Publisher Copyright: © 2023 The Author(s)

PY - 2023/4/4

Y1 - 2023/4/4

N2 - Above-ground biomass (AGB) is considered an essential climate variable that underpins our knowledge and information about the role of forests in mitigating climate change. The availability of satellite-based AGB and AGB change (ΔAGB) products has increased in recent years. Here we assessed the past decade net ΔAGB derived from four recent global multi-date AGB maps: ESA-CCI maps, WRI-Flux model, JPL time series, and SMOS-LVOD time series. Our assessments explore and use different reference data sources with biomass re-measurements within the past decade. The reference data comprise National Forest Inventory (NFI) plot data, local ΔAGB maps from airborne LiDAR, and selected Forest Resource Assessment country data from countries with well-developed monitoring capacities. Map to reference data comparisons were performed at levels ranging from 100 m to 25 km spatial scale. The comparisons revealed that LiDAR data compared most reasonably with the maps, while the comparisons using NFI only showed some agreements at aggregation levels <10 km. Regardless of the aggregation level, AGB losses and gains according to the map comparisons were consistently smaller than the reference data. Map-map comparisons at 25 km highlighted that the maps consistently captured AGB losses in known deforestation hotspots. The comparisons also identified several carbon sink regions consistently detected by all maps. However, disagreement between maps is still large in key forest regions such as the Amazon basin. The overall ΔAGB map cross-correlation between maps varied in the range 0.11–0.29 (r). Reported ΔAGB magnitudes were largest in the high-resolution datasets including the CCI map differencing (stock change) and Flux model (gain-loss) methods, while they were smallest according to the coarser-resolution LVOD and JPL time series products, especially for AGB gains. Our results suggest that ΔAGB assessed from current maps can be biased and any use of the estimates should take that into account. Currently, ΔAGB reference data are sparse especially in the tropics but that deficit can be alleviated by upcoming LiDAR data networks in the context of Supersites and GEO-Trees.

AB - Above-ground biomass (AGB) is considered an essential climate variable that underpins our knowledge and information about the role of forests in mitigating climate change. The availability of satellite-based AGB and AGB change (ΔAGB) products has increased in recent years. Here we assessed the past decade net ΔAGB derived from four recent global multi-date AGB maps: ESA-CCI maps, WRI-Flux model, JPL time series, and SMOS-LVOD time series. Our assessments explore and use different reference data sources with biomass re-measurements within the past decade. The reference data comprise National Forest Inventory (NFI) plot data, local ΔAGB maps from airborne LiDAR, and selected Forest Resource Assessment country data from countries with well-developed monitoring capacities. Map to reference data comparisons were performed at levels ranging from 100 m to 25 km spatial scale. The comparisons revealed that LiDAR data compared most reasonably with the maps, while the comparisons using NFI only showed some agreements at aggregation levels <10 km. Regardless of the aggregation level, AGB losses and gains according to the map comparisons were consistently smaller than the reference data. Map-map comparisons at 25 km highlighted that the maps consistently captured AGB losses in known deforestation hotspots. The comparisons also identified several carbon sink regions consistently detected by all maps. However, disagreement between maps is still large in key forest regions such as the Amazon basin. The overall ΔAGB map cross-correlation between maps varied in the range 0.11–0.29 (r). Reported ΔAGB magnitudes were largest in the high-resolution datasets including the CCI map differencing (stock change) and Flux model (gain-loss) methods, while they were smallest according to the coarser-resolution LVOD and JPL time series products, especially for AGB gains. Our results suggest that ΔAGB assessed from current maps can be biased and any use of the estimates should take that into account. Currently, ΔAGB reference data are sparse especially in the tropics but that deficit can be alleviated by upcoming LiDAR data networks in the context of Supersites and GEO-Trees.

KW - Above-ground biomass

KW - Above-ground biomass change

KW - Carbon flux

KW - Earth observation

KW - Global carbon cycle

KW - Map assessment

UR - http://www.scopus.com/inward/record.url?scp=85151860917&partnerID=8YFLogxK

U2 - 10.1016/j.jag.2023.103274

DO - 10.1016/j.jag.2023.103274

M3 - Article

AN - SCOPUS:85151860917

SN - 1569-8432

VL - 118

JO - International Journal of Applied Earth Observation and Geoinformation

JF - International Journal of Applied Earth Observation and Geoinformation

M1 - 103274

ER -

Past decade above-ground biomass change comparisons from four multi-temporal global maps

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

UN SDGs

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Projects

H2020_ERC_TREEMORT

Cite this