Phenological trajectories of Caribbean very dry tropical forests diverge under different geologic formations

Restrepo, Carla; Delgado, Diana L.; Debrot, Adolphe O.; Vries, A.J. de; Houtepen, Erik; Freitas, John A. de

doi:10.1111/btp.13117

Cited by 1 publication

(1 citation statement)

References 84 publications

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“…Finer-scale edaphic, topographic, or atmospheric differences change species composition. We know that the 30-m cells of multiseason Landsat imagery greatly improve distinction of deciduous and semi-deciduous Caribbean vegetation types, even when climate maps are included as predictors [109], and that Caribbean vegetation phenology [176] and physiognamy [177] can vary among geological substrates. High spatial resolution may account for survival peaks where satellite image bands or phenology metrics imply sparser, shorter, or more deciduous canopies, in drier conditions.…”

Section: Landsat Phenology Multidecadal Imagery and Disturbancementioning

confidence: 99%

Multiscale predictors of small tree survival across a heterogeneous tropical landscape

Helmer

Kay²,

Marcano‐Vega³

et al. 2023

PLoS ONE

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Uncertainties about controls on tree mortality make forest responses to land-use and climate change difficult to predict. We tracked biomass of tree functional groups in tropical forest inventories across Puerto Rico and the U.S. Virgin Islands, and with random forests we ranked 86 potential predictors of small tree survival (young or mature stems 2.5–12.6 cm diameter at breast height). Forests span dry to cloud forests, range in age, geology and past land use and experienced severe drought and storms. When excluding species as a predictor, top predictors are tree crown ratio and height, two to three species traits and stand to regional factors reflecting local disturbance and the system state (widespread recovery, drought, hurricanes). Native species, and species with denser wood, taller maximum height, or medium typical height survive longer, but short trees and species survive hurricanes better. Trees survive longer in older stands and with less disturbed canopies, harsher geoclimates (dry, edaphically dry, e.g., serpentine substrates, and highest-elevation cloud forest), or in intervals removed from hurricanes. Satellite image phenology and bands, even from past decades, are top predictors, being sensitive to vegetation type and disturbance. Covariation between stand-level species traits and geoclimate, disturbance and neighboring species types may explain why most neighbor variables, including introduced vs. native species, had low or no importance, despite univariate correlations with survival. As forests recovered from a hurricane in 1998 and earlier deforestation, small trees of introduced species, which on average have lighter wood, died at twice the rate of natives. After hurricanes in 2017, the total biomass of trees ≥12.7 cm dbh of the introduced species Spathodea campanulata spiked, suggesting that more frequent hurricanes might perpetuate this light-wooded species commonness. If hurricane recovery favors light-wooded species while drought favors others, climate change influences on forest composition and ecosystem services may depend on the frequency and severity of extreme climate events.

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Section: Landsat Phenology Multidecadal Imagery and Disturbancementioning

confidence: 99%