Forest structure and composition alleviate human thermal stress
Current climate change aggravates human health hazards posed by heat stress. Forests can locally mitigate this by acting as strong thermal buffers, yet potential mediation by forest ecological characteristics remains underexplored. We report over 14 months of hourly microclimate data from 131 forest...
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sg-smu-ink.cis_research-10302023-01-19T08:49:37Z Forest structure and composition alleviate human thermal stress GILLEROT, Loïc LANDUYT, Dries OH, Rachel CHOW, Winston T. L. et al, Current climate change aggravates human health hazards posed by heat stress. Forests can locally mitigate this by acting as strong thermal buffers, yet potential mediation by forest ecological characteristics remains underexplored. We report over 14 months of hourly microclimate data from 131 forest plots across four European countries and compare these to open-field controls using physiologically equivalent temperature (PET) to reflect human thermal perception. Forests slightly tempered cold extremes, but the strongest buffering occurred under very hot conditions (PET >35°C), where forests reduced strong to extreme heat stress day occurrence by 84.1%. Mature forests cooled the microclimate by 12.1 to 14.5°C PET under, respectively, strong and extreme heat stress conditions. Even young plantations reduced those conditions by 10°C PET. Forest structure strongly modulated the buffering capacity, which was enhanced by increasing stand density, canopy height and canopy closure. Tree species composition had a more modest yet significant influence: that is, strongly shade-casting, small-leaved evergreen species amplified cooling. Tree diversity had little direct influences, though indirect effects through stand structure remain possible. Forests in general, both young and mature, are thus strong thermal stress reducers, but their cooling potential can be even further amplified, given targeted (urban) forest management that considers these new insights. 2022-12-01T08:00:00Z text application/pdf https://ink.library.smu.edu.sg/cis_research/31 info:doi/10.1111/gcb.16419 https://ink.library.smu.edu.sg/context/cis_research/article/1030/viewcontent/Forest_structure_and_composition_alleviate_human_thermal_stress.pdf http://creativecommons.org/licenses/by-nc-nd/4.0/ Research Collection College of Integrative Studies eng Institutional Knowledge at Singapore Management University Dr. FOREST Forest microclimate Heat stress Nature-based solution Physiologically Equivalent Temperature Thermal comfort Environmental Sciences Urban Studies Urban Studies and Planning |
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Dr. FOREST Forest microclimate Heat stress Nature-based solution Physiologically Equivalent Temperature Thermal comfort Environmental Sciences Urban Studies Urban Studies and Planning GILLEROT, Loïc LANDUYT, Dries OH, Rachel CHOW, Winston T. L. et al, Forest structure and composition alleviate human thermal stress |
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Current climate change aggravates human health hazards posed by heat stress. Forests can locally mitigate this by acting as strong thermal buffers, yet potential mediation by forest ecological characteristics remains underexplored. We report over 14 months of hourly microclimate data from 131 forest plots across four European countries and compare these to open-field controls using physiologically equivalent temperature (PET) to reflect human thermal perception. Forests slightly tempered cold extremes, but the strongest buffering occurred under very hot conditions (PET >35°C), where forests reduced strong to extreme heat stress day occurrence by 84.1%. Mature forests cooled the microclimate by 12.1 to 14.5°C PET under, respectively, strong and extreme heat stress conditions. Even young plantations reduced those conditions by 10°C PET. Forest structure strongly modulated the buffering capacity, which was enhanced by increasing stand density, canopy height and canopy closure. Tree species composition had a more modest yet significant influence: that is, strongly shade-casting, small-leaved evergreen species amplified cooling. Tree diversity had little direct influences, though indirect effects through stand structure remain possible. Forests in general, both young and mature, are thus strong thermal stress reducers, but their cooling potential can be even further amplified, given targeted (urban) forest management that considers these new insights. |
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text |
| author |
GILLEROT, Loïc LANDUYT, Dries OH, Rachel CHOW, Winston T. L. et al, |
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GILLEROT, Loïc LANDUYT, Dries OH, Rachel CHOW, Winston T. L. et al, |
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GILLEROT, Loïc |
| title |
Forest structure and composition alleviate human thermal stress |
| title_short |
Forest structure and composition alleviate human thermal stress |
| title_full |
Forest structure and composition alleviate human thermal stress |
| title_fullStr |
Forest structure and composition alleviate human thermal stress |
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Forest structure and composition alleviate human thermal stress |
| title_sort |
forest structure and composition alleviate human thermal stress |
| publisher |
Institutional Knowledge at Singapore Management University |
| publishDate |
2022 |
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https://ink.library.smu.edu.sg/cis_research/31 https://ink.library.smu.edu.sg/context/cis_research/article/1030/viewcontent/Forest_structure_and_composition_alleviate_human_thermal_stress.pdf |
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