Height-diameter allometry and above ground biomass in tropical montane forests: Insights from the Albertine Rift in Africa

Imani, Gérard; Boyemba, Faustin; Lewis, Simon L.; Nabahungu, Nsharwasi Léon; Calders, Kim; Zapfack, Louis; Riéra, Bernard; Balegamire, Clarisse; Cuní-Sanchez, Aida

doi:10.1371/journal.pone.0179653

Cited by 44 publications

(43 citation statements)

References 80 publications

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“…The observed spatial structure reinforces the dangers of applying allometric relationships validated in different locations, in a limited number of sampling locations or at different spatial scales than the area of interest (e.g., models N1 and N2 were validated from a single site in northeastern Gabon). Of the covariates applied to explain the variation in D:H model bias, soil type was by far the most informative, which is consistent with several previous studies linking soil parameters to AGB estimates (e.g., Cleveland et al 2011, Ledo et al 2016b, Imani et al 2017. The published models typically performed adequately on the two most common soil types (ferralitic and coastal sedimentary), presumably because previously published allometric equations were based on data from these habitat types.…”

Section: Discussionsupporting

confidence: 83%

“…, Imani et al. ). The published models typically performed adequately on the two most common soil types (ferralitic and coastal sedimentary), presumably because previously published allometric equations were based on data from these habitat types.…”

Section: Discussionmentioning

confidence: 99%

“… , b, Imani et al. , Kearsley et al. ), it is the first robust, systematic‐random, landscape scale assessment of the implications of D : H model selection.…”

Section: Discussionmentioning

confidence: 99%

“…Regression models are then fit to the field data to model the relationship between tree diameter and height, from which heights are predicted for all unmeasured trees, and then used in allometric equations to estimate AGB and carbon (e.g., Huang et al 2000, Chave et al 2014, Ngomanda et al 2014. Recently, several studies have compared locally derived models to generic models, finding that variation in tree D:H allometry causes local models to outperform regional models (Kearsley et al 2013, Rutishauser et al 2013, Thomas et al 2015, Ledo et al 2016a,b, Imani et al 2017, Sullivan et al 2018, but see Duque et al 2017, Kearsley et al 2017). However, the causes of variation in model fit and the landscapelevel implications of allometric model selection remain elusive.…”

Section: Introductionmentioning

confidence: 99%

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Landscape‐level validation of allometric relationships for carbon stock estimation reveals bias driven by soil type

Beirne

Miao

Núñez

et al. 2019

Ecological Applications

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Mitigation of climate change depends on accurate estimation and mapping of terrestrial carbon stocks, particularly in carbon dense tropical forests. Allometric equations can be used to robustly estimate biomass of tropical trees, but often require tree height, which is frequently unknown. Researchers and practitioners must, therefore, decide whether to directly measure a subset of tree heights to develop diameter : height (D:H) equations or rely on previously published generic equations. To date, studies comparing the two approaches have been spatially restricted and/or not randomly allocated across the landscape of interest, making the implications of deciding whether or not to measure tree heights difficult to determine. To address this issue, we use inventory data from a systematic-random forest inventory across Gabon (102 forest sites; 42,627 trees, including 7,036 height-measured trees). Using plot-specific models of D:H as a benchmark, we compare the performance of a suite of locally fitted and commonly used generic models (parameterized national, georegional, and pantropical equations) across a variety of scales, and assess which abiotic, anthropogenic, and topographical covariates contribute the most to bias in height estimation. We reveal marked spatial structure in the magnitude and direction of bias in tree height estimation using all generic models, due at least in part to soil type, which compounded to substantial error in site-level AGB estimates (of up to 38% or 150 Mg/ha). However, two generic pantropical models (Chave 2014; Feldpausch 2012) converged to within 2.5% of mean AGB at the landscape scale. Our results suggest that some (not all) pantropical equations can extrapolate AGB across large spatial scales with minimal bias in estimated mean AGB. However, extreme caution must be taken when interpreting the AGB estimates from generic models at the site-level as they fail to capture substantial spatial variation in D:H relationships, which could lead to dramatic under-or over-estimation of site-level carbon stocks. Validated allometric models derived at site-or soil-type-levels may be the best way to reduce such biases arising from landscape-level heterogeneity in D:H model fit in the Afrotropics.

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Section: Discussionsupporting

confidence: 83%

Section: Discussionmentioning

confidence: 99%

“… , b, Imani et al. , Kearsley et al. ), it is the first robust, systematic‐random, landscape scale assessment of the implications of D : H model selection.…”

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Landscape‐level validation of allometric relationships for carbon stock estimation reveals bias driven by soil type

Beirne

Miao

Núñez

et al. 2019

Ecological Applications

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“…Biomass in each part of the plant increases proportionately with the larger diameter of the tree. The high ability of trees to store carbon free from air depends on the diameter of trees (Imani et al 2017) and tree height (Fu and Wu 2011). The estimated of total carbon stock value in the Perancak Estuary is 22.18±11.76 tonC ha -1 and the amount of CO2 sequestration estimation is 81.41±43.18 tonC ha -1 .…”

Section: Resultsmentioning

confidence: 99%

Carbon Stock Estimation of Mangrove Vegetation Using Remote Sensing in Perancak Estuary, Jembrana District, Bali

Hastuti¹,

Suniada²,

Islamy³

2018

IJReSES

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Abstract. Mangrove vegetation is one of the forest ecosystems that offers a potential of substantial greenhouse gases (GHG) emission mitigation, due to its ability to sink the amount of CO2 in the atmosphere through the photosynthesis process. Mangroves have been providing multiple benefits either as the source of food, the habitat of wildlife, the coastline protectors as well as the CO2 absorber, higher than other forest types. To explore the role of mangrove vegetation in sequestering the carbon stock, the study on the use of remotely sensed data in estimating carbon stock was applied. This paper describes an examination of the use of remote sensing data particularly Landsat-

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Saltcedar (Tamarix mascatensis) inhibits growth and spatial distribution of eshnan (Seidlitzia rosmarinus) by enrichment of soil salinity in a semi-arid desert

Erfanifard

Khosravi

2019

Plant Soil

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Height-diameter allometry and above ground biomass in tropical montane forests: Insights from the Albertine Rift in Africa

Cited by 44 publications

References 80 publications

Landscape‐level validation of allometric relationships for carbon stock estimation reveals bias driven by soil type

Landscape‐level validation of allometric relationships for carbon stock estimation reveals bias driven by soil type

Carbon Stock Estimation of Mangrove Vegetation Using Remote Sensing in Perancak Estuary, Jembrana District, Bali

Saltcedar (Tamarix mascatensis) inhibits growth and spatial distribution of eshnan (Seidlitzia rosmarinus) by enrichment of soil salinity in a semi-arid desert

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