Height-diameter allometry of tropical forest trees

T.R. Feldpausch; L. Banin; O.L. Phillips; T.R. Baker; S.L. Lewis; C.A. Quesada; K. Affum-Baffoe; E.J.M.M. Arets; N.J. Berry; M. Bird; E.S. Brondizio; P. de Camargo; J. Chave; G. Djagbletey; T.F. Domingues; M. Drescher; P.M. Fearnside; M.B. Franca; N.M. Fyllas; G. Lopez-Gonzalez; A. Hladik; N. Higuchi; M.O. Hunter; Y. Iida; K.A. Salim; A.R. Kassim; M. Keller; J. Kemp; D.A. King; J.C. Lovett; B.S. Marimon; B.H. Marimon-Junior; E. Lenza; A.R. Marshall; D.J. Metcalfe; E.T.A. Mitchard; E.F. Moran; B.W. Nelson; R. Nilus; E.M. Nogueira; M. Palace; S. Patino; K.S.H. Peh; M.T. Raventos; J.M. Reitsma; G. Saiz; F. Schrodt; B. Sonké; H.E. Taedoumg; S. Tan; L. White; H. Wöll; J. Lloyd

doi:10.5194/bg-8-1081-2011

Height-diameter allometry of tropical forest trees

T.R. Feldpausch, L. Banin, O.L. Phillips, T.R. Baker, S.L. Lewis, C.A. Quesada, K. Affum-Baffoe, E.J.M.M. Arets, N.J. Berry, M. Bird, E.S. Brondizio, P. de Camargo, J. Chave, G. Djagbletey, T.F. Domingues, M. Drescher, P.M. Fearnside, M.B. Franca, N.M. Fyllas, G. Lopez-GonzalezA. Hladik, N. Higuchi, M.O. Hunter, Y. Iida, K.A. Salim, A.R. Kassim, M. Keller, J. Kemp, D.A. King, J.C. Lovett, B.S. Marimon, B.H. Marimon-Junior, E. Lenza, A.R. Marshall, D.J. Metcalfe, E.T.A. Mitchard, E.F. Moran, B.W. Nelson, R. Nilus, E.M. Nogueira, M. Palace, S. Patino, K.S.H. Peh, M.T. Raventos, J.M. Reitsma, G. Saiz, F. Schrodt, B. Sonké, H.E. Taedoumg, S. Tan, L. White, H. Wöll, J. Lloyd

Wageningen Environmental Research

Research output: Contribution to journal › Article › Academic › peer-review

435 Citations (Scopus)

Abstract

Tropical tree height-diameter (H:D) relationships may vary by forest type and region making large-scale estimates of above-ground biomass subject to bias if they ignore these differences in stem allometry. We have therefore developed a new global tropical forest database consisting of 39 955 concurrent H and D measurements encompassing 283 sites in 22 tropical countries. Utilising this database, our objectives were: 1. to determine if H:D relationships differ by geographic region and forest type (wet to dry forests, including zones of tension where forest and savanna overlap). 2. to ascertain if the H:D relationship is modulated by climate and/or forest structural characteristics (e.g. stand-level basal area, A). 3. to develop H:D allometric equations and evaluate biases to reduce error in future local-to-global estimates of tropical forest biomass. Annual precipitation coefficient of variation (PV), dry season length (SD), and mean annual air temperature (TA) emerged as key drivers of variation in H:D relationships at the pantropical and region scales. Vegetation structure also played a role with trees in forests of a high A being, on average, taller at any given D. After the effects of environment and forest structure are taken into account, two main regional groups can be identified. Forests in Asia, Africa and the Guyana Shield all have, on average, similar H:D relationships, but with trees in the forests of much of the Amazon Basin and tropical Australia typically being shorter at any given D than their counterparts elsewhere. The region-environment-structure model with the lowest Akaike's information criterion and lowest deviation estimated stand-level H across all plots to within amedian -2.7 to 0.9% of the true value. Some of the plot-to-plot variability in H:D relationships not accounted for by this model could be attributed to variations in soil physical conditions. Other things being equal, trees tend to be more slender in the absence of soil physical constraints, especially at smaller D. Pantropical and continental-level models provided less robust estimates of H, especially when the roles of climate and stand structure in modulating H:D allometry were not simultaneously taken into account.

Original language	English
Pages (from-to)	1081-1106
Journal	Biogeosciences
Volume	8
DOIs	https://doi.org/10.5194/bg-8-1081-2011
Publication status	Published - 2011

Keywords

amazon rain-forest
elfin cloud forest
leaf gas-exchange
montane forest
aboveground biomass
spatial-patterns
hydraulic architecture
altitudinal transect
environmental-change
neotropical forest

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10.5194/bg-8-1081-2011

Cite this

Feldpausch, T. R., Banin, L., Phillips, O. L., Baker, T. R., Lewis, S. L., Quesada, C. A., Affum-Baffoe, K., Arets, E. J. M. M., Berry, N. J., Bird, M., Brondizio, E. S., de Camargo, P., Chave, J., Djagbletey, G., Domingues, T. F., Drescher, M., Fearnside, P. M., Franca, M. B., Fyllas, N. M., ... Lloyd, J. (2011). Height-diameter allometry of tropical forest trees. Biogeosciences, 8, 1081-1106. https://doi.org/10.5194/bg-8-1081-2011

@article{aa5f69b0ee834c1cb1f673ded2f79a24,

title = "Height-diameter allometry of tropical forest trees",

abstract = "Tropical tree height-diameter (H:D) relationships may vary by forest type and region making large-scale estimates of above-ground biomass subject to bias if they ignore these differences in stem allometry. We have therefore developed a new global tropical forest database consisting of 39 955 concurrent H and D measurements encompassing 283 sites in 22 tropical countries. Utilising this database, our objectives were: 1. to determine if H:D relationships differ by geographic region and forest type (wet to dry forests, including zones of tension where forest and savanna overlap). 2. to ascertain if the H:D relationship is modulated by climate and/or forest structural characteristics (e.g. stand-level basal area, A). 3. to develop H:D allometric equations and evaluate biases to reduce error in future local-to-global estimates of tropical forest biomass. Annual precipitation coefficient of variation (PV), dry season length (SD), and mean annual air temperature (TA) emerged as key drivers of variation in H:D relationships at the pantropical and region scales. Vegetation structure also played a role with trees in forests of a high A being, on average, taller at any given D. After the effects of environment and forest structure are taken into account, two main regional groups can be identified. Forests in Asia, Africa and the Guyana Shield all have, on average, similar H:D relationships, but with trees in the forests of much of the Amazon Basin and tropical Australia typically being shorter at any given D than their counterparts elsewhere. The region-environment-structure model with the lowest Akaike's information criterion and lowest deviation estimated stand-level H across all plots to within amedian -2.7 to 0.9% of the true value. Some of the plot-to-plot variability in H:D relationships not accounted for by this model could be attributed to variations in soil physical conditions. Other things being equal, trees tend to be more slender in the absence of soil physical constraints, especially at smaller D. Pantropical and continental-level models provided less robust estimates of H, especially when the roles of climate and stand structure in modulating H:D allometry were not simultaneously taken into account.",

keywords = "amazon rain-forest, elfin cloud forest, leaf gas-exchange, montane forest, aboveground biomass, spatial-patterns, hydraulic architecture, altitudinal transect, environmental-change, neotropical forest",

author = "T.R. Feldpausch and L. Banin and O.L. Phillips and T.R. Baker and S.L. Lewis and C.A. Quesada and K. Affum-Baffoe and E.J.M.M. Arets and N.J. Berry and M. Bird and E.S. Brondizio and {de Camargo}, P. and J. Chave and G. Djagbletey and T.F. Domingues and M. Drescher and P.M. Fearnside and M.B. Franca and N.M. Fyllas and G. Lopez-Gonzalez and A. Hladik and N. Higuchi and M.O. Hunter and Y. Iida and K.A. Salim and A.R. Kassim and M. Keller and J. Kemp and D.A. King and J.C. Lovett and B.S. Marimon and B.H. Marimon-Junior and E. Lenza and A.R. Marshall and D.J. Metcalfe and E.T.A. Mitchard and E.F. Moran and B.W. Nelson and R. Nilus and E.M. Nogueira and M. Palace and S. Patino and K.S.H. Peh and M.T. Raventos and J.M. Reitsma and G. Saiz and F. Schrodt and B. Sonk{\'e} and H.E. Taedoumg and S. Tan and L. White and H. W{\"o}ll and J. Lloyd",

year = "2011",

doi = "10.5194/bg-8-1081-2011",

language = "English",

volume = "8",

pages = "1081--1106",

journal = "Biogeosciences",

issn = "1726-4170",

publisher = "European Geosciences Union",

}

Feldpausch, TR, Banin, L, Phillips, OL, Baker, TR, Lewis, SL, Quesada, CA, Affum-Baffoe, K, Arets, EJMM, Berry, NJ, Bird, M, Brondizio, ES, de Camargo, P, Chave, J, Djagbletey, G, Domingues, TF, Drescher, M, Fearnside, PM, Franca, MB, Fyllas, NM, Lopez-Gonzalez, G, Hladik, A, Higuchi, N, Hunter, MO, Iida, Y, Salim, KA, Kassim, AR, Keller, M, Kemp, J, King, DA, Lovett, JC, Marimon, BS, Marimon-Junior, BH, Lenza, E, Marshall, AR, Metcalfe, DJ, Mitchard, ETA, Moran, EF, Nelson, BW, Nilus, R, Nogueira, EM, Palace, M, Patino, S, Peh, KSH, Raventos, MT, Reitsma, JM, Saiz, G, Schrodt, F, Sonké, B, Taedoumg, HE, Tan, S, White, L, Wöll, H & Lloyd, J 2011, 'Height-diameter allometry of tropical forest trees', Biogeosciences, vol. 8, pp. 1081-1106. https://doi.org/10.5194/bg-8-1081-2011

TY - JOUR

T1 - Height-diameter allometry of tropical forest trees

AU - Feldpausch, T.R.

AU - Banin, L.

AU - Phillips, O.L.

AU - Baker, T.R.

AU - Lewis, S.L.

AU - Quesada, C.A.

AU - Affum-Baffoe, K.

AU - Arets, E.J.M.M.

AU - Berry, N.J.

AU - Bird, M.

AU - Brondizio, E.S.

AU - de Camargo, P.

AU - Chave, J.

AU - Djagbletey, G.

AU - Domingues, T.F.

AU - Drescher, M.

AU - Fearnside, P.M.

AU - Franca, M.B.

AU - Fyllas, N.M.

AU - Lopez-Gonzalez, G.

AU - Hladik, A.

AU - Higuchi, N.

AU - Hunter, M.O.

AU - Iida, Y.

AU - Salim, K.A.

AU - Kassim, A.R.

AU - Keller, M.

AU - Kemp, J.

AU - King, D.A.

AU - Lovett, J.C.

AU - Marimon, B.S.

AU - Marimon-Junior, B.H.

AU - Lenza, E.

AU - Marshall, A.R.

AU - Metcalfe, D.J.

AU - Mitchard, E.T.A.

AU - Moran, E.F.

AU - Nelson, B.W.

AU - Nilus, R.

AU - Nogueira, E.M.

AU - Palace, M.

AU - Patino, S.

AU - Peh, K.S.H.

AU - Raventos, M.T.

AU - Reitsma, J.M.

AU - Saiz, G.

AU - Schrodt, F.

AU - Sonké, B.

AU - Taedoumg, H.E.

AU - Tan, S.

AU - White, L.

AU - Wöll, H.

AU - Lloyd, J.

PY - 2011

Y1 - 2011

N2 - Tropical tree height-diameter (H:D) relationships may vary by forest type and region making large-scale estimates of above-ground biomass subject to bias if they ignore these differences in stem allometry. We have therefore developed a new global tropical forest database consisting of 39 955 concurrent H and D measurements encompassing 283 sites in 22 tropical countries. Utilising this database, our objectives were: 1. to determine if H:D relationships differ by geographic region and forest type (wet to dry forests, including zones of tension where forest and savanna overlap). 2. to ascertain if the H:D relationship is modulated by climate and/or forest structural characteristics (e.g. stand-level basal area, A). 3. to develop H:D allometric equations and evaluate biases to reduce error in future local-to-global estimates of tropical forest biomass. Annual precipitation coefficient of variation (PV), dry season length (SD), and mean annual air temperature (TA) emerged as key drivers of variation in H:D relationships at the pantropical and region scales. Vegetation structure also played a role with trees in forests of a high A being, on average, taller at any given D. After the effects of environment and forest structure are taken into account, two main regional groups can be identified. Forests in Asia, Africa and the Guyana Shield all have, on average, similar H:D relationships, but with trees in the forests of much of the Amazon Basin and tropical Australia typically being shorter at any given D than their counterparts elsewhere. The region-environment-structure model with the lowest Akaike's information criterion and lowest deviation estimated stand-level H across all plots to within amedian -2.7 to 0.9% of the true value. Some of the plot-to-plot variability in H:D relationships not accounted for by this model could be attributed to variations in soil physical conditions. Other things being equal, trees tend to be more slender in the absence of soil physical constraints, especially at smaller D. Pantropical and continental-level models provided less robust estimates of H, especially when the roles of climate and stand structure in modulating H:D allometry were not simultaneously taken into account.

AB - Tropical tree height-diameter (H:D) relationships may vary by forest type and region making large-scale estimates of above-ground biomass subject to bias if they ignore these differences in stem allometry. We have therefore developed a new global tropical forest database consisting of 39 955 concurrent H and D measurements encompassing 283 sites in 22 tropical countries. Utilising this database, our objectives were: 1. to determine if H:D relationships differ by geographic region and forest type (wet to dry forests, including zones of tension where forest and savanna overlap). 2. to ascertain if the H:D relationship is modulated by climate and/or forest structural characteristics (e.g. stand-level basal area, A). 3. to develop H:D allometric equations and evaluate biases to reduce error in future local-to-global estimates of tropical forest biomass. Annual precipitation coefficient of variation (PV), dry season length (SD), and mean annual air temperature (TA) emerged as key drivers of variation in H:D relationships at the pantropical and region scales. Vegetation structure also played a role with trees in forests of a high A being, on average, taller at any given D. After the effects of environment and forest structure are taken into account, two main regional groups can be identified. Forests in Asia, Africa and the Guyana Shield all have, on average, similar H:D relationships, but with trees in the forests of much of the Amazon Basin and tropical Australia typically being shorter at any given D than their counterparts elsewhere. The region-environment-structure model with the lowest Akaike's information criterion and lowest deviation estimated stand-level H across all plots to within amedian -2.7 to 0.9% of the true value. Some of the plot-to-plot variability in H:D relationships not accounted for by this model could be attributed to variations in soil physical conditions. Other things being equal, trees tend to be more slender in the absence of soil physical constraints, especially at smaller D. Pantropical and continental-level models provided less robust estimates of H, especially when the roles of climate and stand structure in modulating H:D allometry were not simultaneously taken into account.

KW - amazon rain-forest

KW - elfin cloud forest

KW - leaf gas-exchange

KW - montane forest

KW - aboveground biomass

KW - spatial-patterns

KW - hydraulic architecture

KW - altitudinal transect

KW - environmental-change

KW - neotropical forest

U2 - 10.5194/bg-8-1081-2011

DO - 10.5194/bg-8-1081-2011

M3 - Article

SN - 1726-4170

VL - 8

SP - 1081

EP - 1106

JO - Biogeosciences

JF - Biogeosciences

ER -

Height-diameter allometry of tropical forest trees

Abstract

Keywords

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