TY - JOUR
T1 - New tree height allometries derived from terrestrial laser scanning reveal substantial discrepancies with forest inventory methods in tropical rainforests
AU - Terryn, Louise
AU - Calders, Kim
AU - Meunier, Félicien
AU - Bauters, Marijn
AU - Boeckx, Pascal
AU - Brede, Benjamin
AU - Burt, Andrew
AU - Chave, Jerome
AU - da Costa, Antonio Carlos Lola
AU - D'hont, Barbara
AU - Disney, Mathias
AU - Jucker, Tommaso
AU - Lau, Alvaro
AU - Laurance, Susan G.W.
AU - Maeda, Eduardo Eiji
AU - Meir, Patrick
AU - Krishna Moorthy, Sruthi M.
AU - Nunes, Matheus Henrique
AU - Shenkin, Alexander
AU - Sibret, Thomas
AU - Verhelst, Tom E.
AU - Wilkes, Phil
AU - Verbeeck, Hans
N1 - Publisher Copyright:
© 2024 The Author(s). Global Change Biology published by John Wiley & Sons Ltd.
PY - 2024/8/19
Y1 - 2024/8/19
N2 - Tree allometric models, essential for monitoring and predicting terrestrial carbon stocks, are traditionally built on global databases with forest inventory measurements of stem diameter (D) and tree height (H). However, these databases often combine H measurements obtained through various measurement methods, each with distinct error patterns, affecting the resulting H:D allometries. In recent decades, terrestrial laser scanning (TLS) has emerged as a widely accepted method for accurate, non-destructive tree structural measurements. This study used TLS data to evaluate the prediction accuracy of forest inventory-based H:D allometries and to develop more accurate pantropical allometries. We considered 19 tropical rainforest plots across four continents. Eleven plots had forest inventory and RIEGL VZ-400(i) TLS-based D and H data, allowing accuracy assessment of local forest inventory-based H:D allometries. Additionally, TLS-based data from 1951 trees from all 19 plots were used to create new pantropical H:D allometries for tropical rainforests. Our findings reveal that in most plots, forest inventory-based H:D allometries underestimated H compared with TLS-based allometries. For 30-metre-tall trees, these underestimations varied from −1.6 m (−5.3%) to −7.5 m (−25.4%). In the Malaysian plot with trees reaching up to 77 m in height, the underestimation was as much as −31.7 m (−41.3%). We propose a TLS-based pantropical H:D allometry, incorporating maximum climatological water deficit for site effects, with a mean uncertainty of 19.1% and a mean bias of −4.8%. While the mean uncertainty is roughly 2.3% greater than that of the Chave2014 model, this model demonstrates more consistent uncertainties across tree size and delivers less biased estimates of H (with a reduction of 8.23%). In summary, recognizing the errors in H measurements from forest inventory methods is vital, as they can propagate into the allometries they inform. This study underscores the potential of TLS for accurate H and D measurements in tropical rainforests, essential for refining tree allometries.
AB - Tree allometric models, essential for monitoring and predicting terrestrial carbon stocks, are traditionally built on global databases with forest inventory measurements of stem diameter (D) and tree height (H). However, these databases often combine H measurements obtained through various measurement methods, each with distinct error patterns, affecting the resulting H:D allometries. In recent decades, terrestrial laser scanning (TLS) has emerged as a widely accepted method for accurate, non-destructive tree structural measurements. This study used TLS data to evaluate the prediction accuracy of forest inventory-based H:D allometries and to develop more accurate pantropical allometries. We considered 19 tropical rainforest plots across four continents. Eleven plots had forest inventory and RIEGL VZ-400(i) TLS-based D and H data, allowing accuracy assessment of local forest inventory-based H:D allometries. Additionally, TLS-based data from 1951 trees from all 19 plots were used to create new pantropical H:D allometries for tropical rainforests. Our findings reveal that in most plots, forest inventory-based H:D allometries underestimated H compared with TLS-based allometries. For 30-metre-tall trees, these underestimations varied from −1.6 m (−5.3%) to −7.5 m (−25.4%). In the Malaysian plot with trees reaching up to 77 m in height, the underestimation was as much as −31.7 m (−41.3%). We propose a TLS-based pantropical H:D allometry, incorporating maximum climatological water deficit for site effects, with a mean uncertainty of 19.1% and a mean bias of −4.8%. While the mean uncertainty is roughly 2.3% greater than that of the Chave2014 model, this model demonstrates more consistent uncertainties across tree size and delivers less biased estimates of H (with a reduction of 8.23%). In summary, recognizing the errors in H measurements from forest inventory methods is vital, as they can propagate into the allometries they inform. This study underscores the potential of TLS for accurate H and D measurements in tropical rainforests, essential for refining tree allometries.
KW - accuracy
KW - forest inventory
KW - terrestrial laser scanning
KW - tree allometry
KW - tree height
KW - tropical rainforest
UR - http://www.scopus.com/inward/record.url?scp=85201534830&partnerID=8YFLogxK
U2 - 10.1111/gcb.17473
DO - 10.1111/gcb.17473
M3 - Article (Academic Journal)
C2 - 39155688
AN - SCOPUS:85201534830
SN - 1354-1013
VL - 30
JO - Global Change Biology
JF - Global Change Biology
IS - 8
M1 - e17473
ER -