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Canopy structure and topography jointly constrain the microclimate of human-modified tropical landscapes

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Canopy structure and topography jointly constrain the microclimate of human-modified tropical landscapes. / Jucker, T.; Hardwick, S.R.; Both, S. et al.
In: Global Change Biology, Vol. 24, No. 11, 11.2018, p. 5243-5258.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Jucker, T, Hardwick, SR, Both, S, Elias, DMO, Ewers, RM, Milodowski, DT, Swinfield, T & Coomes, DA 2018, 'Canopy structure and topography jointly constrain the microclimate of human-modified tropical landscapes', Global Change Biology, vol. 24, no. 11, pp. 5243-5258. https://doi.org/10.1111/gcb.14415

APA

Jucker, T., Hardwick, S. R., Both, S., Elias, D. M. O., Ewers, R. M., Milodowski, D. T., Swinfield, T., & Coomes, D. A. (2018). Canopy structure and topography jointly constrain the microclimate of human-modified tropical landscapes. Global Change Biology, 24(11), 5243-5258. https://doi.org/10.1111/gcb.14415

Vancouver

Jucker T, Hardwick SR, Both S, Elias DMO, Ewers RM, Milodowski DT et al. Canopy structure and topography jointly constrain the microclimate of human-modified tropical landscapes. Global Change Biology. 2018 Nov;24(11):5243-5258. Epub 2018 Sept 23. doi: 10.1111/gcb.14415

Author

Jucker, T. ; Hardwick, S.R. ; Both, S. et al. / Canopy structure and topography jointly constrain the microclimate of human-modified tropical landscapes. In: Global Change Biology. 2018 ; Vol. 24, No. 11. pp. 5243-5258.

Bibtex

@article{e2f2c80a712f4005aa37878be79bccec,
title = "Canopy structure and topography jointly constrain the microclimate of human-modified tropical landscapes",
abstract = "Local-scale microclimatic conditions in forest understoreys play a key role in shaping the composition, diversity and function of these ecosystems. Consequently, understanding what drives variation in forest microclimate is critical to forecasting ecosystem responses to global change, particularly in the tropics where many species already operate close to their thermal limits and rapid land-use transformation is profoundly altering local environments. Yet our ability to characterize forest microclimate at ecologically meaningful scales remains limited, as understorey conditions cannot be directly measured from outside the canopy. To address this challenge, we established a network of microclimate sensors across a land-use intensity gradient spanning from old-growth forests to oil-palm plantations in Borneo. We then combined these observations with high-resolution airborne laser scanning data to characterize how topography and canopy structure shape variation in microclimate both locally and across the landscape. In the processes, we generated high-resolution microclimate surfaces spanning over 350 km2, which we used to explore the potential impacts of habitat degradation on forest regeneration under both current and future climate scenarios. We found that topography and vegetation structure were strong predictors of local microclimate, with elevation and terrain curvature primarily constraining daily mean temperatures and vapour pressure deficit (VPD), whereas canopy height had a clear dampening effect on microclimate extremes. This buffering effect was particularly pronounced on wind-exposed slopes but tended to saturate once canopy height exceeded 20 m—suggesting that despite intensive logging, secondary forests remain largely thermally buffered. Nonetheless, at a landscape-scale microclimate was highly heterogeneous, with maximum daily temperatures ranging between 24.2 and 37.2°C and VPD spanning two orders of magnitude. Based on this, we estimate that by the end of the century forest regeneration could be hampered in degraded secondary forests that characterize much of Borneo's lowlands if temperatures continue to rise following projected trends. {\textcopyright} 2018 The Authors. Global Change Biology Published by John Wiley & Sons Ltd",
keywords = "canopy height, digital elevation model, forest degradation and fragmentation, LiDAR, near-surface air temperature, remote sensing, selective logging, vapour pressure deficit, Elaeis",
author = "T. Jucker and S.R. Hardwick and S. Both and D.M.O. Elias and R.M. Ewers and D.T. Milodowski and T. Swinfield and D.A. Coomes",
year = "2018",
month = nov,
doi = "10.1111/gcb.14415",
language = "English",
volume = "24",
pages = "5243--5258",
journal = "Global Change Biology",
issn = "1354-1013",
publisher = "Blackwell Publishing Ltd",
number = "11",

}

RIS

TY - JOUR

T1 - Canopy structure and topography jointly constrain the microclimate of human-modified tropical landscapes

AU - Jucker, T.

AU - Hardwick, S.R.

AU - Both, S.

AU - Elias, D.M.O.

AU - Ewers, R.M.

AU - Milodowski, D.T.

AU - Swinfield, T.

AU - Coomes, D.A.

PY - 2018/11

Y1 - 2018/11

N2 - Local-scale microclimatic conditions in forest understoreys play a key role in shaping the composition, diversity and function of these ecosystems. Consequently, understanding what drives variation in forest microclimate is critical to forecasting ecosystem responses to global change, particularly in the tropics where many species already operate close to their thermal limits and rapid land-use transformation is profoundly altering local environments. Yet our ability to characterize forest microclimate at ecologically meaningful scales remains limited, as understorey conditions cannot be directly measured from outside the canopy. To address this challenge, we established a network of microclimate sensors across a land-use intensity gradient spanning from old-growth forests to oil-palm plantations in Borneo. We then combined these observations with high-resolution airborne laser scanning data to characterize how topography and canopy structure shape variation in microclimate both locally and across the landscape. In the processes, we generated high-resolution microclimate surfaces spanning over 350 km2, which we used to explore the potential impacts of habitat degradation on forest regeneration under both current and future climate scenarios. We found that topography and vegetation structure were strong predictors of local microclimate, with elevation and terrain curvature primarily constraining daily mean temperatures and vapour pressure deficit (VPD), whereas canopy height had a clear dampening effect on microclimate extremes. This buffering effect was particularly pronounced on wind-exposed slopes but tended to saturate once canopy height exceeded 20 m—suggesting that despite intensive logging, secondary forests remain largely thermally buffered. Nonetheless, at a landscape-scale microclimate was highly heterogeneous, with maximum daily temperatures ranging between 24.2 and 37.2°C and VPD spanning two orders of magnitude. Based on this, we estimate that by the end of the century forest regeneration could be hampered in degraded secondary forests that characterize much of Borneo's lowlands if temperatures continue to rise following projected trends. © 2018 The Authors. Global Change Biology Published by John Wiley & Sons Ltd

AB - Local-scale microclimatic conditions in forest understoreys play a key role in shaping the composition, diversity and function of these ecosystems. Consequently, understanding what drives variation in forest microclimate is critical to forecasting ecosystem responses to global change, particularly in the tropics where many species already operate close to their thermal limits and rapid land-use transformation is profoundly altering local environments. Yet our ability to characterize forest microclimate at ecologically meaningful scales remains limited, as understorey conditions cannot be directly measured from outside the canopy. To address this challenge, we established a network of microclimate sensors across a land-use intensity gradient spanning from old-growth forests to oil-palm plantations in Borneo. We then combined these observations with high-resolution airborne laser scanning data to characterize how topography and canopy structure shape variation in microclimate both locally and across the landscape. In the processes, we generated high-resolution microclimate surfaces spanning over 350 km2, which we used to explore the potential impacts of habitat degradation on forest regeneration under both current and future climate scenarios. We found that topography and vegetation structure were strong predictors of local microclimate, with elevation and terrain curvature primarily constraining daily mean temperatures and vapour pressure deficit (VPD), whereas canopy height had a clear dampening effect on microclimate extremes. This buffering effect was particularly pronounced on wind-exposed slopes but tended to saturate once canopy height exceeded 20 m—suggesting that despite intensive logging, secondary forests remain largely thermally buffered. Nonetheless, at a landscape-scale microclimate was highly heterogeneous, with maximum daily temperatures ranging between 24.2 and 37.2°C and VPD spanning two orders of magnitude. Based on this, we estimate that by the end of the century forest regeneration could be hampered in degraded secondary forests that characterize much of Borneo's lowlands if temperatures continue to rise following projected trends. © 2018 The Authors. Global Change Biology Published by John Wiley & Sons Ltd

KW - canopy height

KW - digital elevation model

KW - forest degradation and fragmentation

KW - LiDAR

KW - near-surface air temperature

KW - remote sensing

KW - selective logging

KW - vapour pressure deficit

KW - Elaeis

U2 - 10.1111/gcb.14415

DO - 10.1111/gcb.14415

M3 - Journal article

VL - 24

SP - 5243

EP - 5258

JO - Global Change Biology

JF - Global Change Biology

SN - 1354-1013

IS - 11

ER -