Tropical forest light regimes in a human‐modified landscape

Fauset, Sophie; Gloor, Manuel; Aidar, Marcos Pereira Marinho; Freitas, Helber C.; Fyllas, Nikolaos M.; Marabesi, Mauro Alexandre; Rochelle, André Luis Casarin; Shenkin, Alexander; Vieira, Simone A.; Joly, Carlos A.

doi:10.1002/ecs2.2002

Cited by 33 publications

(27 citation statements)

References 79 publications

(149 reference statements)

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“…Disturbance severity modified the subcanopy light environment and exerted mixed effects on leaf traits. Deeper canopy light penetration is widely observed at higher disturbance severities (Fauset et al, 2017; Turton & Siegenthaler, 2004) as is increased light spatial homogeneity as canopies become more uniformly open (Chazdon & Fetcher, 1984). We incorrectly anticipated that at high disturbance severities, a more homogenous and enriched subcanopy light environment would consistently augment leaf trait uniformity and promote sun leaf physiology and morphology.…”

Section: Discussionmentioning

confidence: 99%

Forest structure, diversity, and primary production in relation to disturbance severity

Haber

Fahey

Wales

et al. 2020

Ecology and Evolution

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1. Differential disturbance severity effects on forest vegetation structure, species diversity, and net primary production (NPP) have been long theorized and observed. Here, we examined these factors concurrently to explore the potential for a mechanistic pathway linking disturbance severity, changes in light environment, leaf functional response, and wood NPP in a temperate hardwood forest.2. Using a suite of measurements spanning an experimental gradient of tree mortality, we evaluated the direction and magnitude of change in vegetation structural and diversity indexes in relation to wood NPP. Informed by prior observations, we hypothesized that forest structural and species diversity changes and wood NPP would exhibit either a linear, unimodal, or threshold response in relation to disturbance severity. We expected increasing disturbance severity would progressively shift subcanopy light availability and leaf traits, thereby coupling structural and species diversity changes with primary production.3. Linear or unimodal changes in three of four vegetation structural indexes were observed across the gradient in disturbance severity. However, disturbance-related changes in vegetation structure were not consistently correlated with shifts in light environment, leaf traits, and wood NPP. Species diversity indexes did not change in response to rising disturbance severity.4. We conclude that, in our study system, the sensitivity of wood NPP to rising disturbance severity is generally tied to changing vegetation structure but not species diversity. Changes in vegetation structure are inconsistently coupled with light environment and leaf traits, resulting in mixed support for our hypothesized cascade linking disturbance severity to wood NPP.

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Section: Discussionmentioning

confidence: 99%

Forest structure, diversity, and primary production in relation to disturbance severity

Haber

Fahey

Wales

et al. 2020

Ecology and Evolution

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“…Related to this, we need to understand what physiological and behavioral strategies species adopt to cope with or evade unfavorable microclimates. For instance, mobile species might shift from diurnal to nocturnal activity to escape warmer temperatures (Davison et al, 2019;Levy et al, 2019), while sessile organisms such as plants can thermoregulate by increasing transpiration and adjusting leaf angles (Fauset et al, 2017). Alternatively, some species may be able to rapidly acclimate and/or adapt to novel microclimates, as was recently shown for a poison frog in Costa Rica that exhibits higher preferred body temperatures in forests that have been logged (Rivera-Ordonez et al, 2019).…”

Section: Species Distributions and Population Dynamicsmentioning

confidence: 99%

“…But perhaps the most pervasive impact of logging is that by opening and thinning the canopy, it increases solar radiation and air flow in the understorey and decreases evapotranspiration-thereby altering the forest's microclimate (Breshears, 2006;Hardwick et al, 2015;Senior et al, 2017). As a result, not only do logged forests tend to be warmer, drier and brighter than old-growth ones (Hardwick et al, 2015;Fauset et al, 2017;Senior et al, 2017), but microclimatic conditions in these human-modified ecosystems are also more spatially and temporally heterogeneous (Hardwick et al, 2015;Blonder et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

A Research Agenda for Microclimate Ecology in Human-Modified Tropical Forests

Jucker

Jackson

Zellweger

et al. 2020

Front. For. Glob. Change

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Logging and habitat fragmentation impact tropical forest ecosystems in numerous ways, perhaps the most striking of which is by altering the temperature, humidity, and light environment of the forest-its microclimate. Because local-scale microclimatic conditions directly influence the physiology, demography and behavior of most species, many of the impacts of land-use intensification on the biodiversity and ecosystem functioning of tropical forests have been attributed to changes in microclimate. However, the actual pathways through which altered microclimatic conditions reshape the ecology of these human-modified ecosystems remain largely unexplored. To bridge this knowledge gap, here we outline an agenda for future microclimate research in human-modified tropical ecosystems. We focus specifically on three main themes: the role of microclimate in shaping (i) species distributions, (ii) species interactions, and (iii) ecosystem functioning in tropical forests. In doing so we aim to highlight how a renewed focus on microclimate can help us not only better understand the ecology of human-modified tropical ecosystems, but also guide efforts to manage and protect them.

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“…Disturbances can affect tropical forests' ability to buffer changes in their microclimate from changes in broader-scale climate (Ewers and Banks-Leite, 2013;De Frenne and Verheyen, 2016). For example, selective logging may cause reductions in canopy closure that in turn drive increased radiation and airflow, which then lead to decreased broad-scale climate buffering and higher variation in microclimate (Fauset et al, 2017). The extent of these effects remains controversial (Senior et al, 2017b).…”

Section: Introductionmentioning

confidence: 99%

Extreme and Highly Heterogeneous Microclimates in Selectively Logged Tropical Forests

Blonder

Both

Coomes

et al. 2018

Front. For. Glob. Change

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Microclimate within forests influences ecosystem fluxes and demographic rates. Anthropogenic disturbances, such as selective logging can affect within-forest microclimate through effects on forest structure, leading to indirect effects on forests beyond the immediate impact of logging. However, the scope and predictability of these effects remains poorly understood. Here we use a microclimate thermal proxy (sensitive to radiative, convective, and conductive heat fluxes) measured at the forest floor in three 1-ha forest plots spanning a logging intensity gradient in Malaysian Borneo. We show (1) that thermal proxy ranges and spatiotemporal heterogeneity are doubled between old growth and heavily logged forests, with extremes often exceeding 45 • C, (2) that nearby weather station air temperatures provide estimates of maximum thermal proxy values that are biased down by 5-10 • C, and (3) that lower canopy density, higher canopy height, and higher biomass removal are associated with higher maximum temperatures. Thus, logged forests are less buffered from regional climate change than old growth forests, and experience much higher microclimate extremes and heterogeneity. Better predicting the linkages between regional climate and its effects on within-forest microclimate will be critical for understanding the wide range of conditions experienced within tropical forests.

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Tropical forest light regimes in a human‐modified landscape

Cited by 33 publications

References 79 publications

Forest structure, diversity, and primary production in relation to disturbance severity

Forest structure, diversity, and primary production in relation to disturbance severity

A Research Agenda for Microclimate Ecology in Human-Modified Tropical Forests

Extreme and Highly Heterogeneous Microclimates in Selectively Logged Tropical Forests

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