Variation in trunk taper of buttressed trees within and among five lowland tropical forests

K. C. Cushman; Sarayudh Bunyavejchewin; Dairon Cárdenas; Richard Condit; Stuart J. Davies; Álvaro Duque; Stephen P. Hubbell; Somboon Kiratiprayoon; Shawn K.Y. Lum; Helene C. Muller-Landau

doi:10.1111/btp.12994

Variation in trunk taper of buttressed trees within and among five lowland tropical forests

K. C. Cushman, Sarayudh Bunyavejchewin, Dairon Cárdenas, Richard Condit, Stuart J. Davies, Álvaro Duque, Stephen P. Hubbell, Somboon Kiratiprayoon, Shawn K.Y. Lum, Helene C. Muller-Landau

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

10 Scopus citations

Abstract

Accurately projecting global carbon dynamics requires understanding controls over temporal and spatial tropical forest biomass variation. Changes in tropical forest aboveground biomass per area are most commonly estimated using repeat forest plot censuses, but errors in these estimates can be relatively large, limiting our ability to detect real changes in forest carbon. One source of error is nonstandard heights of diameter measurement, which are common in tropical forests because buttressed trees are usually measured above buttresses. Nonstandard and temporally variable measurement heights affect biomass change estimates because tree trunks taper—higher measurements result in smaller diameters and, thus, smaller estimated biomass. Modeling trunk taper is a potential way to correct for biases associated with nonstandard and changing measurement heights. We measured trunk taper for 260 buttressed trees in five lowland tropical forests to assess variation in taper within and among sites. Trunks taper more slowly in trees with larger diameters above buttress, taller buttresses, and higher wood density; these variables together explain 29% of taper variation. We also used plot data to quantify the distribution of measurement heights—and potential for bias in biomass estimates. We found significant variation in measurement heights among plots, and over time within plots. At the site level, our general taper model (taper predicted from diameter above buttress, buttress height, and wood density) produced site-level biomass estimates within 3.4%, on average, of estimates from measured taper. We recommend using this model to reduce bias from nonstandard measurement heights in studies of tropical forest biomass variation. Abstract in Spanish is available with online material.

Original language	English
Pages (from-to)	1442-1453
Number of pages	12
Journal	Biotropica
Volume	53
Issue number	5
DOIs	https://doi.org/10.1111/btp.12994
State	Published - Sep 2021
Externally published	Yes

Funding

This project was supported by a CTFS-ForestGEO Grants Program award to KCC and HCM. KCC was also supported as part of the Next Generation Ecosystem Experiments-Tropics, funded by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research. We thank Evan Gora and Raquel Araujo for providing comments on the manuscript; Mr. Sompoch Maneerat and Mr. Komon Jaisawang for supporting fieldwork at the Khao Chong and Huai Kha Khaeng field stations; and Juan Sebastian Barreto, Modh Fairoz, Emily Francis, Jonathan Goh, Pui San Ho, Pitoon Kongnoo, Gabriel Jordán López, Ruben Mark, Pablo Ramos, Paulino Villareal, and Tom Weinland for assistance with fieldwork, logistics, and hospitality. The BCI forest dynamics research project was founded by S.P. Hubbell and R.B. Foster and is now managed by S. Aguilar, R. Condit, S. Lao, and R. Pérez under ForestGEO and the Smithsonian Tropical Research in Panama. Numerous organizations have provided funding, principally the U.S. National Science Foundation, and hundreds of field workers have contributed. This project was supported by a CTFS‐ForestGEO Grants Program award to KCC and HCM. KCC was also supported as part of the Next Generation Ecosystem Experiments‐Tropics, funded by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research. We thank Evan Gora and Raquel Araujo for providing comments on the manuscript; Mr. Sompoch Maneerat and Mr. Komon Jaisawang for supporting fieldwork at the Khao Chong and Huai Kha Khaeng field stations; and Juan Sebastian Barreto, Modh Fairoz, Emily Francis, Jonathan Goh, Pui San Ho, Pitoon Kongnoo, Gabriel Jordán López, Ruben Mark, Pablo Ramos, Paulino Villareal, and Tom Weinland for assistance with fieldwork, logistics, and hospitality. The BCI forest dynamics research project was founded by S.P. Hubbell and R.B. Foster and is now managed by S. Aguilar, R. Condit, S. Lao, and R. Pérez under ForestGEO and the Smithsonian Tropical Research in Panama. Numerous organizations have provided funding, principally the U.S. National Science Foundation, and hundreds of field workers have contributed.

Keywords

aboveground biomass
buttressed trees
forest dynamics
forest plots
measurement error
photogrammetry
tropical forest
trunk taper

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10.1111/btp.12994

Cite this

@article{e050facf91aa459d8b17ee08e32b805c,

title = "Variation in trunk taper of buttressed trees within and among five lowland tropical forests",

abstract = "Accurately projecting global carbon dynamics requires understanding controls over temporal and spatial tropical forest biomass variation. Changes in tropical forest aboveground biomass per area are most commonly estimated using repeat forest plot censuses, but errors in these estimates can be relatively large, limiting our ability to detect real changes in forest carbon. One source of error is nonstandard heights of diameter measurement, which are common in tropical forests because buttressed trees are usually measured above buttresses. Nonstandard and temporally variable measurement heights affect biomass change estimates because tree trunks taper—higher measurements result in smaller diameters and, thus, smaller estimated biomass. Modeling trunk taper is a potential way to correct for biases associated with nonstandard and changing measurement heights. We measured trunk taper for 260 buttressed trees in five lowland tropical forests to assess variation in taper within and among sites. Trunks taper more slowly in trees with larger diameters above buttress, taller buttresses, and higher wood density; these variables together explain 29% of taper variation. We also used plot data to quantify the distribution of measurement heights—and potential for bias in biomass estimates. We found significant variation in measurement heights among plots, and over time within plots. At the site level, our general taper model (taper predicted from diameter above buttress, buttress height, and wood density) produced site-level biomass estimates within 3.4%, on average, of estimates from measured taper. We recommend using this model to reduce bias from nonstandard measurement heights in studies of tropical forest biomass variation. Abstract in Spanish is available with online material.",

keywords = "aboveground biomass, buttressed trees, forest dynamics, forest plots, measurement error, photogrammetry, tropical forest, trunk taper",

author = "Cushman, {K. C.} and Sarayudh Bunyavejchewin and Dairon C{\'a}rdenas and Richard Condit and Davies, {Stuart J.} and {\'A}lvaro Duque and Hubbell, {Stephen P.} and Somboon Kiratiprayoon and Lum, {Shawn K.Y.} and Muller-Landau, {Helene C.}",

note = "Publisher Copyright: {\textcopyright} 2021 The Association for Tropical Biology and Conservation",

year = "2021",

month = sep,

doi = "10.1111/btp.12994",

language = "English",

volume = "53",

pages = "1442--1453",

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issn = "0006-3606",

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T1 - Variation in trunk taper of buttressed trees within and among five lowland tropical forests

AU - Cushman, K. C.

AU - Bunyavejchewin, Sarayudh

AU - Cárdenas, Dairon

AU - Condit, Richard

AU - Davies, Stuart J.

AU - Duque, Álvaro

AU - Hubbell, Stephen P.

AU - Kiratiprayoon, Somboon

AU - Lum, Shawn K.Y.

AU - Muller-Landau, Helene C.

PY - 2021/9

Y1 - 2021/9

N2 - Accurately projecting global carbon dynamics requires understanding controls over temporal and spatial tropical forest biomass variation. Changes in tropical forest aboveground biomass per area are most commonly estimated using repeat forest plot censuses, but errors in these estimates can be relatively large, limiting our ability to detect real changes in forest carbon. One source of error is nonstandard heights of diameter measurement, which are common in tropical forests because buttressed trees are usually measured above buttresses. Nonstandard and temporally variable measurement heights affect biomass change estimates because tree trunks taper—higher measurements result in smaller diameters and, thus, smaller estimated biomass. Modeling trunk taper is a potential way to correct for biases associated with nonstandard and changing measurement heights. We measured trunk taper for 260 buttressed trees in five lowland tropical forests to assess variation in taper within and among sites. Trunks taper more slowly in trees with larger diameters above buttress, taller buttresses, and higher wood density; these variables together explain 29% of taper variation. We also used plot data to quantify the distribution of measurement heights—and potential for bias in biomass estimates. We found significant variation in measurement heights among plots, and over time within plots. At the site level, our general taper model (taper predicted from diameter above buttress, buttress height, and wood density) produced site-level biomass estimates within 3.4%, on average, of estimates from measured taper. We recommend using this model to reduce bias from nonstandard measurement heights in studies of tropical forest biomass variation. Abstract in Spanish is available with online material.

AB - Accurately projecting global carbon dynamics requires understanding controls over temporal and spatial tropical forest biomass variation. Changes in tropical forest aboveground biomass per area are most commonly estimated using repeat forest plot censuses, but errors in these estimates can be relatively large, limiting our ability to detect real changes in forest carbon. One source of error is nonstandard heights of diameter measurement, which are common in tropical forests because buttressed trees are usually measured above buttresses. Nonstandard and temporally variable measurement heights affect biomass change estimates because tree trunks taper—higher measurements result in smaller diameters and, thus, smaller estimated biomass. Modeling trunk taper is a potential way to correct for biases associated with nonstandard and changing measurement heights. We measured trunk taper for 260 buttressed trees in five lowland tropical forests to assess variation in taper within and among sites. Trunks taper more slowly in trees with larger diameters above buttress, taller buttresses, and higher wood density; these variables together explain 29% of taper variation. We also used plot data to quantify the distribution of measurement heights—and potential for bias in biomass estimates. We found significant variation in measurement heights among plots, and over time within plots. At the site level, our general taper model (taper predicted from diameter above buttress, buttress height, and wood density) produced site-level biomass estimates within 3.4%, on average, of estimates from measured taper. We recommend using this model to reduce bias from nonstandard measurement heights in studies of tropical forest biomass variation. Abstract in Spanish is available with online material.

KW - aboveground biomass

KW - buttressed trees

KW - forest dynamics

KW - forest plots

KW - measurement error

KW - photogrammetry

KW - tropical forest

KW - trunk taper

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U2 - 10.1111/btp.12994

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EP - 1453

JO - Biotropica

JF - Biotropica

IS - 5

ER -

Variation in trunk taper of buttressed trees within and among five lowland tropical forests

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