Strong Discrepancies between Local Temperature Mapping and Interpolated Climatic Grids in Tropical Mountainous Agricultural Landscapes

Faye, Émile; Herrera, Mario; Bellomo, Lucio; Silvain, Jean‐François; Dangles, Olivier

doi:10.1371/journal.pone.0105541

Cited by 32 publications

(39 citation statements)

References 39 publications

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“…Thus, it is likely that our estimates of the current mean annual temperatures are slight over‐ or underestimations of the actual conditions experienced by the respective species (Faye et al . ). It has also become increasingly clear that temperature ranges, frequencies of moisture supply, or the extent and frequency of extreme events may have more predictive power than average conditions (e.g.…”

Section: Discussionmentioning

confidence: 97%

‘Are 3 °C too much?’: thermal niche breadth in Bromeliaceae and global warming

2016

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Summary By the end of this century, temperature is predicted to increase by about 6 °C at higher latitudes and about 3 °C in the tropics. Although values predicted for tropical latitudes are lower, rising temperatures in the tropics are likely to have more severe consequences for tropical species that are generally assumed to have narrower climatic niches due to a higher degree of climatic stability and higher niche specialization. Even though temperature affects all ontogenetic stages, the regeneration niche of a species is fundamental for overall niche breadth and hence represents a potential major bottleneck for its distribution. We conducted germination experiments along a range of temperatures with 41 epiphytic bromeliad species to determine thermal germination traits (thermal niche breadth, lower and upper thermal limit, thermal optimum). Based on these traits, we asked whether the thermal germination niche breadth of these species is wide enough to cope with the predicted increase in temperature. Furthermore, we conducted phylogenetic comparative analyses to detect possible niche conservatism of these traits in Bromeliaceae. For 93% of all tested bromeliad species, the predicted mean annual temperature range does not exceed the thermal niche breadth. Moreover, for 85% of all tested species, the current mean annual temperature across the distribution range is well below our estimates of their thermal optima. Furthermore, we found evidence for phylogenetic niche conservatism in most assessed traits. Synthesis. Our report represents an important first step to understand and predict present and future responses of epiphytic bromeliads to global warming. At least with regard to seed germination, epiphytic bromeliads should not be negatively affected by the predicted temperature rise of 3 °C. To the contrary, future temperatures are closer to the thermal optima of most species, potentially leading to an increase in performance. However, since niche conservatism in Bromeliaceae may limit their adaptability to novel climatic conditions, a negative effect of increasing temperatures cannot be completely rejected when considering ontogenetic niche shifts.

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Section: Discussionmentioning

confidence: 97%

‘Are 3 °C too much?’: thermal niche breadth in Bromeliaceae and global warming

2016

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“…Additionally, the fact that both thermal limits exhibit a similar rate of evolutionary change and that CTmax exhibits a slightly lower phylogenetic signal, at least in Pagel's λ, contradicts the general view of conservatism of upper thermal tolerance assuming depauperate evolutionary potential to face upcoming increasing heat (Araújo et al., ; Grigg & Buckley, ; Hoffmann et al., ; Muñoz et al., ). Second, the assumed relevance of interpolated coarse‐resolution climate to organismal body temperatures is in most cases unsustained, exhibiting high spatial bias in topographically complex and environmentally heterogeneous areas, such as mountain regions (Dobrowski, ; Faye, Herrera, Bellomo, Silvain, & Dangles, ; Fridley, ). This inaccurate mapping of actual exposure temperatures at the local scale may compromise our ability to project vulnerability assessments to ongoing global climatic predictions (Sunday et al., ).…”

Section: Discussionmentioning

confidence: 99%

Elevational and microclimatic drivers of thermal tolerance in Andean Pristimantis frogs

Pintanel

Tejedo

Ron

et al. 2019

Journal of Biogeography

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Aim We analysed elevational and microclimatic drivers of thermal tolerance diversity in a tropical mountain frog clade to test three macrophysiological predictions: less spatial variation in upper than lower thermal limits (Bretts’ heat‐invariant hypothesis); narrower thermal tolerance ranges in habitats with less variation in temperature (Janzen's climatic variability hypothesis); and higher level of heat impacts at lower elevations. Location Forest and open habitats through a 4,230‐m elevational gradient across the tropical Andes of Ecuador. Method We examined variability in critical thermal limits (CTmax and CTmin) and thermal breadth (TB; CTmax–CTmin) in 21 species of Pristimantis frogs. Additionally, we monitored maximum and minimum temperatures at the local scale (tmax, tmin) and estimated vulnerability to acute thermal stress from heat (CTmax–tmax) and cold (tmin–CTmin), by partitioning thermal diversity into elevational and microclimatic variation. Results Our results were consistent with Brett's hypothesis: elevation promotes more variation in CTmin and tmin than in CTmax and tmax. Frogs inhabiting thermally variable open habitats have higher CTmax and tmax and greater TBs than species restricted to forest habitats, which show less climatic overlap across the elevational gradient (Janzen's hypothesis). Vulnerability to heat stress was higher in open than forest habitats and did not vary with elevation. Main conclusions We suggest a mechanistic explanation of thermal tolerance diversity in elevational gradients by including microclimatic thermal variation. We propose that the unfeasibility to buffer minimum temperatures locally may explain the rapid increase in cold tolerance (lower CTmin) with elevation. In contrast, the relative invariability in heat tolerance (CTmax) with elevation may revolve around the organisms’ habitat selection of open‐ and canopy‐buffered habitats. Secondly, on the basis of microclimatic estimates, lowland and upland species may be equally vulnerable to temperature increase, which is contrary to the pattern inferred from regional interpolated climate estimators.

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“…Here, we applied our toolbox to the study of the spatial heterogeneity in surface temperatures in agricultural landscapes (Faye et al . ), with the view to assessing how microscale thermal features of crop fields change across plant phenology. Our study was conducted in an Andean agricultural landscape located in the Cotopaxi province of Ecuador.…”

Section: Study Casementioning

confidence: 99%

“…Microclimatic conditions can deviate substantially from those represented by gridded climatic layers (Faye et al . ; Hannah et al . ; Scheffers et al .…”

Section: Introductionmentioning

confidence: 99%

A toolbox for studying thermal heterogeneity across spatial scales: from unmanned aerial vehicle imagery to landscape metrics

et al. 2015

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1.A major barrier for the scientific community of climate change biologists is the spatial mismatch between the size of organisms and the resolution at which global climate data are collected and modelled. Thus, the development of integrative and quantitative tools for the monitoring and spatial characterization of microclimates across spatial scales is a key issue for climate change ecologists. 2. We proposed an integrative toolbox for quantifying the spatial heterogeneity in surface temperatures by bringing together procedures of unmanned aerial vehicles, thermal imagery, orthomosaic, GIS classification and spatial metrics. This toolbox permits to yield high-resolution visual and infrared orthoimages that are processed into a GIS for selecting surfaces of interest in the landscape (e.g. soil, vegetation). Then, the thermal matrices of selected surfaces (i.e. temperature values of the pixels belonging to the selected surfaces only) are processed within R to generate a variety of thermal landscape metrics (e.g. thermal patch richness and density, thermal aggregation and cohesion index). 3. We applied this toolbox to the thermal characterization of mountainous agricultural landscapes in Ecuador with implications for ectothermic pest dynamics. UAV flights at a height of 60 m above-ground level allowed us to acquired high-resolution visual and thermal images (1 and 5 cm/pixel, respectively) for 12 potato fields with a mean surface of 1017 AE 117 m 2 . Landscape metrics on plant and soil surfaces showed that crop phenology drives the spatial patterns of surface temperatures and strongly modifies the overall thermal ecology of crop fields, with potential implications for ectothermic pest occurrence and dynamics. 4. Overall, our toolbox affords a timely and innovative methodological framework to better assess the thermal heterogeneity of natural landscapes across a wide range of spatial scales. In particular, this toolbox would be of topical interest for ecologists trying to bridge the gap between the resolution of their climatic data and the body size of their study organisms.

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Strong Discrepancies between Local Temperature Mapping and Interpolated Climatic Grids in Tropical Mountainous Agricultural Landscapes

Cited by 32 publications

References 39 publications

‘Are 3 °C too much?’: thermal niche breadth in Bromeliaceae and global warming

‘Are 3 °C too much?’: thermal niche breadth in Bromeliaceae and global warming

Elevational and microclimatic drivers of thermal tolerance in Andean Pristimantis frogs

A toolbox for studying thermal heterogeneity across spatial scales: from unmanned aerial vehicle imagery to landscape metrics

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