Large‐scale impacts of selective logging on canopy tree beta‐diversity in the Brazilian Amazon

Bousfield, Christopher G.; Massam, Mike R.; Peres, Carlos A.; Edwards, David P.

doi:10.1111/1365-2664.14403

Cited by 6 publications

(1 citation statement)

References 80 publications

(111 reference statements)

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“…Selective logging is the primary form of timber production in Southeast Asia, which targets mature, commercially valuable individuals of dominant species, causes changes in canopy coverage, height, tree density, and leaf area index (LAI. Slik et al, 2013;Bousfield et al, 2023;Santos et al, 2024). This disruption reduces thermal buffering, enhancing evaporation while potentially suppressing canopy transpiration (Senior et al, 2010;Jucker et al, 2018;Santos et al, 2024), which together brings uncertainties to total ET and soil moisture.…”

Section: Introductionmentioning

confidence: 99%

A regime shift in soil moisture triggered by selective logging in Bornean lowland tropical rainforests

Qin,

Aoyagi,

Takeshige

et al. 2024

Preprint

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Context Aboveground biomass removal and canopy opening by selective logging modifies soil moisture in the main root zone, impacting soil aeration and various biogeochemical processes in tropical production forests. Objectives This study investigated the relationship between canopy damages and topsoil (10 cm) moisture in logged-over forests in Malaysian Borneo, controlling for logging intensity, time elapsed from logging, and spatial autocorrelation. Methods Volumetric soil water content (VSWC), canopy height model (CHM), leaf area index (LAI), and historical logging data were collected from 84 transects in 15 sites exhibiting varying canopies. Principal component analysis (PCA) was applied to canopy structure metrics (CSM) derived from CHM and LAI for each transect. The first principal component (PC1) quantified canopy structural degradation and was analyzed in comparison to topography for the relationship with VSWC across logging periods. VSWC spatial autocorrelation was examined in relation to canopy conditions. Results VSWC increased from 0.27 m3 m− 3 to over 0.4 m3 m− 3 after logging. In the study area, PC1 was a stronger predictor of VSWC than topography was. Wettest soils were found underneath the most degraded canopies, despite of a higher evaporative demand combined with higher vapor pressure deficit. Conclusions This study revealed soil wetting after selective logging in humid tropical forests, driven by reduced transpiration from biomass loss rather than increased evaporative demand from canopy opening. The elevated soil water regime could disrupt carbon and nitrogen cycling and impede forest succession, and its coupling with increased evaporative demand increases the overall vulnerability of disturbed tropical rainforests.

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Section: Introductionmentioning

confidence: 99%