TY - JOUR
T1 - Global carbon balance of the forest
T2 - satellite-based L-VOD results over the last decade
AU - Wigneron, Jean-Pierre
AU - Ciais, Philippe
AU - Li, Xiaojun
AU - Brandt, Martin
AU - Canadell, Josep G.
AU - Tian, Feng
AU - Wang, Huan
AU - Bastos, Ana
AU - Fan, Lei
AU - Gatica, Gabriel
AU - Kashyap, Rahul
AU - Liu, Xiangzhuo
AU - Sitch, Stephen
AU - Tao, Shengli
AU - Xiao, Xiangming
AU - Yang, Hui
AU - Villar, Jhan Carlo Espinoza
AU - Frappart, Frederic
AU - Li, Wei
AU - Qin, Yuanwei
AU - De Truchis, Aurélien
AU - Fensholt, Rasmus
N1 - Publisher Copyright:
Copyright © 2024 Wigneron, Ciais, Li, Brandt, Canadell, Tian, Wang, Bastos, Fan, Gatica, Kashyap, Liu, Sitch, Tao, Xiao, Yang, Espinoza Villar, Frappart, Li, Qin, De Truchis and Fensholt.
PY - 2024
Y1 - 2024
N2 - Monitoring forest carbon (C) stocks is essential to better assess their role in the global carbon balance, and to better model and predict long-term trends and inter-annual variability in atmospheric CO2 concentrations. On a national scale, national forest inventories (NFIs) can provide estimates of forest carbon stocks, but these estimates are only available in certain countries, are limited by time lags due to periodic revisits, and cannot provide spatially continuous mapping of forests. In this context, remote sensing offers many advantages for monitoring above-ground biomass (AGB) on a global scale with good spatial (50–100 m) and temporal (annual) resolutions. Remote sensing has been used for several decades to monitor vegetation. However, traditional methods of monitoring AGB using optical or microwave sensors are affected by saturation effects for moderately or densely vegetated canopies, limiting their performance. Low-frequency passive microwave remote sensing is less affected by these saturation effects: saturation only occurs at AGB levels of around 400 t/ha at L-band (frequency of around 1.4 GHz). Despite its coarse spatial resolution of the order of 25 km × 25 km, this method based on the L-VOD (vegetation optical depth at L-band) index has recently established itself as an essential approach for monitoring annual variations in forest AGB on a continental scale. Thus, L-VOD has been applied to forest monitoring in many continents and biomes: in the tropics (especially in the Amazon and Congo basins), in boreal regions (Siberia, Canada), in Europe, China, Australia, etc. However, no reference study has yet been published to analyze L-VOD in detail in terms of capabilities, validation and results. This paper fills this gap by presenting the physical principles of L-VOD calculation, analyzing the performance of L-VOD for monitoring AGB and reviewing the main applications of L-VOD for tracking the carbon balance of global vegetation over the last decade (2010–2019).
AB - Monitoring forest carbon (C) stocks is essential to better assess their role in the global carbon balance, and to better model and predict long-term trends and inter-annual variability in atmospheric CO2 concentrations. On a national scale, national forest inventories (NFIs) can provide estimates of forest carbon stocks, but these estimates are only available in certain countries, are limited by time lags due to periodic revisits, and cannot provide spatially continuous mapping of forests. In this context, remote sensing offers many advantages for monitoring above-ground biomass (AGB) on a global scale with good spatial (50–100 m) and temporal (annual) resolutions. Remote sensing has been used for several decades to monitor vegetation. However, traditional methods of monitoring AGB using optical or microwave sensors are affected by saturation effects for moderately or densely vegetated canopies, limiting their performance. Low-frequency passive microwave remote sensing is less affected by these saturation effects: saturation only occurs at AGB levels of around 400 t/ha at L-band (frequency of around 1.4 GHz). Despite its coarse spatial resolution of the order of 25 km × 25 km, this method based on the L-VOD (vegetation optical depth at L-band) index has recently established itself as an essential approach for monitoring annual variations in forest AGB on a continental scale. Thus, L-VOD has been applied to forest monitoring in many continents and biomes: in the tropics (especially in the Amazon and Congo basins), in boreal regions (Siberia, Canada), in Europe, China, Australia, etc. However, no reference study has yet been published to analyze L-VOD in detail in terms of capabilities, validation and results. This paper fills this gap by presenting the physical principles of L-VOD calculation, analyzing the performance of L-VOD for monitoring AGB and reviewing the main applications of L-VOD for tracking the carbon balance of global vegetation over the last decade (2010–2019).
KW - biomass
KW - forest
KW - global carbon cycle
KW - L-VOD
KW - passive microwave
U2 - 10.3389/frsen.2024.1338618
DO - 10.3389/frsen.2024.1338618
M3 - Review
AN - SCOPUS:85193942083
VL - 5
JO - Frontiers in Remote Sensing
JF - Frontiers in Remote Sensing
SN - 2673-6187
M1 - 1338618
ER -