Changes in Land Cover and Management Affect Heat Stress and Labor Capacity

Anton Orlov; Steven De Hertog; Felix Havermann; Suqi Guo; Fei Luo; Iris Manola; Wim Thiery; Quentin Lejeune; Julia Pongratz; Florian Humpenöder; Michael Windisch; Shruti Nath; Alexander Popp; Carl-Friedrich Schleussner

doi:10.1029/2022EF002909

Changes in Land Cover and Management Affect Heat Stress and Labor Capacity

Anton Orlov, Steven De Hertog, Felix Havermann, Suqi Guo, Fei Luo, Iris Manola, Wim Thiery, Quentin Lejeune, Julia Pongratz, Florian Humpenöder, Michael Windisch, Shruti Nath, Alexander Popp, Carl-Friedrich Schleussner

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Abstract

Abstract Global warming is expected to exacerbate heat stress. Additionally, biogeophysical effects of land cover and land management changes (LCLMC) could substantially alter temperature and relative humidity locally and non-locally. Thereby, LCLMC could affect the occupational capacity to safely perform physical work under hot environments (labor capacity). However, these effects have never been quantified globally using a multi-model setup. Building on results from stylized sensitivity experiments of (a) cropland expansion, (b) irrigation expansion, and (c) afforestation conducted by three fully coupled Earth System Models (ESMs), we assess the local as well as non-local effects on heat stress and labor capacity. We found that LCLMC leads to substantial changes in temperature; however, the concomitant changes in humidity could largely diminish the combined impact on moist heat. Moreover, cropland expansion and afforestation cause inconsistent responses of day- and night-time temperature, which has strong implications for labor capacity. Across the ESMs, the results are mixed in terms of sign and magnitude. Overall, LCLMC result in non-negligible impacts on heat stress and labor capacity in low-latitude regions during the warmest seasons. In some locations, the changes of monthly average labor capacity, which are induced by the local effects of individual LCLMC options, could reach −14 and +15 percentage points. Thus, LCLMC-induced impacts on heat stress and their consequences for adaptation should be accounted for when designing LCLMC-related policies to ensure sustainable development.

Original language	English
Article number	e2022EF002909
Number of pages	20
Journal	Earth's Future
Volume	11
Issue number	3
DOIs	https://doi.org/10.1029/2022EF002909
Publication status	Published - 23 Mar 2023

Bibliographical note

Funding Information:
We thank an anonymous reviewer for the thorough review and valuable comments to our manuscript. This study was funded by the Research Council of Norway and co-funded by the European Union through the project “LAnd MAnagement for CLImate Mitigation and Adaptation” (LAMACLIMA) (Grant 300478), which is part of ERA4CS, an ERA-NET initiated by JPI Climate.

Funding Information:
We thank an anonymous reviewer for the thorough review and valuable comments to our manuscript. This study was funded by the Research Council of Norway and co‐funded by the European Union through the project “LAnd MAnagement for CLImate Mitigation and Adaptation” (LAMACLIMA) (Grant 300478), which is part of ERA4CS, an ERA‐NET initiated by JPI Climate.

Publisher Copyright:
© 2023 The Authors.

Copyright:
Copyright 2023 Elsevier B.V., All rights reserved.

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Orlov_etal_2023_EFFinal published version, 9.18 MBLicence: CC BY-NC

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title = "Changes in Land Cover and Management Affect Heat Stress and Labor Capacity",

abstract = "Abstract Global warming is expected to exacerbate heat stress. Additionally, biogeophysical effects of land cover and land management changes (LCLMC) could substantially alter temperature and relative humidity locally and non-locally. Thereby, LCLMC could affect the occupational capacity to safely perform physical work under hot environments (labor capacity). However, these effects have never been quantified globally using a multi-model setup. Building on results from stylized sensitivity experiments of (a) cropland expansion, (b) irrigation expansion, and (c) afforestation conducted by three fully coupled Earth System Models (ESMs), we assess the local as well as non-local effects on heat stress and labor capacity. We found that LCLMC leads to substantial changes in temperature; however, the concomitant changes in humidity could largely diminish the combined impact on moist heat. Moreover, cropland expansion and afforestation cause inconsistent responses of day- and night-time temperature, which has strong implications for labor capacity. Across the ESMs, the results are mixed in terms of sign and magnitude. Overall, LCLMC result in non-negligible impacts on heat stress and labor capacity in low-latitude regions during the warmest seasons. In some locations, the changes of monthly average labor capacity, which are induced by the local effects of individual LCLMC options, could reach −14 and +15 percentage points. Thus, LCLMC-induced impacts on heat stress and their consequences for adaptation should be accounted for when designing LCLMC-related policies to ensure sustainable development.",

keywords = "land cover, land management, heat stress, labor capacity, labor productivity, sustainability",

author = "Anton Orlov and {De Hertog}, Steven and Felix Havermann and Suqi Guo and Fei Luo and Iris Manola and Wim Thiery and Quentin Lejeune and Julia Pongratz and Florian Humpen{\"o}der and Michael Windisch and Shruti Nath and Alexander Popp and Carl-Friedrich Schleussner",

note = "Funding Information: We thank an anonymous reviewer for the thorough review and valuable comments to our manuscript. This study was funded by the Research Council of Norway and co-funded by the European Union through the project “LAnd MAnagement for CLImate Mitigation and Adaptation” (LAMACLIMA) (Grant 300478), which is part of ERA4CS, an ERA-NET initiated by JPI Climate. Funding Information: We thank an anonymous reviewer for the thorough review and valuable comments to our manuscript. This study was funded by the Research Council of Norway and co‐funded by the European Union through the project “LAnd MAnagement for CLImate Mitigation and Adaptation” (LAMACLIMA) (Grant 300478), which is part of ERA4CS, an ERA‐NET initiated by JPI Climate. Publisher Copyright: {\textcopyright} 2023 The Authors. Copyright: Copyright 2023 Elsevier B.V., All rights reserved.",

year = "2023",

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doi = "10.1029/2022EF002909",

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AU - Orlov, Anton

AU - De Hertog, Steven

AU - Havermann, Felix

AU - Guo, Suqi

AU - Luo, Fei

AU - Manola, Iris

AU - Thiery, Wim

AU - Lejeune, Quentin

AU - Pongratz, Julia

AU - Humpenöder, Florian

AU - Windisch, Michael

AU - Nath, Shruti

AU - Popp, Alexander

AU - Schleussner, Carl-Friedrich

N1 - Funding Information: We thank an anonymous reviewer for the thorough review and valuable comments to our manuscript. This study was funded by the Research Council of Norway and co-funded by the European Union through the project “LAnd MAnagement for CLImate Mitigation and Adaptation” (LAMACLIMA) (Grant 300478), which is part of ERA4CS, an ERA-NET initiated by JPI Climate. Funding Information: We thank an anonymous reviewer for the thorough review and valuable comments to our manuscript. This study was funded by the Research Council of Norway and co‐funded by the European Union through the project “LAnd MAnagement for CLImate Mitigation and Adaptation” (LAMACLIMA) (Grant 300478), which is part of ERA4CS, an ERA‐NET initiated by JPI Climate. Publisher Copyright: © 2023 The Authors. Copyright: Copyright 2023 Elsevier B.V., All rights reserved.

PY - 2023/3/23

Y1 - 2023/3/23

N2 - Abstract Global warming is expected to exacerbate heat stress. Additionally, biogeophysical effects of land cover and land management changes (LCLMC) could substantially alter temperature and relative humidity locally and non-locally. Thereby, LCLMC could affect the occupational capacity to safely perform physical work under hot environments (labor capacity). However, these effects have never been quantified globally using a multi-model setup. Building on results from stylized sensitivity experiments of (a) cropland expansion, (b) irrigation expansion, and (c) afforestation conducted by three fully coupled Earth System Models (ESMs), we assess the local as well as non-local effects on heat stress and labor capacity. We found that LCLMC leads to substantial changes in temperature; however, the concomitant changes in humidity could largely diminish the combined impact on moist heat. Moreover, cropland expansion and afforestation cause inconsistent responses of day- and night-time temperature, which has strong implications for labor capacity. Across the ESMs, the results are mixed in terms of sign and magnitude. Overall, LCLMC result in non-negligible impacts on heat stress and labor capacity in low-latitude regions during the warmest seasons. In some locations, the changes of monthly average labor capacity, which are induced by the local effects of individual LCLMC options, could reach −14 and +15 percentage points. Thus, LCLMC-induced impacts on heat stress and their consequences for adaptation should be accounted for when designing LCLMC-related policies to ensure sustainable development.

AB - Abstract Global warming is expected to exacerbate heat stress. Additionally, biogeophysical effects of land cover and land management changes (LCLMC) could substantially alter temperature and relative humidity locally and non-locally. Thereby, LCLMC could affect the occupational capacity to safely perform physical work under hot environments (labor capacity). However, these effects have never been quantified globally using a multi-model setup. Building on results from stylized sensitivity experiments of (a) cropland expansion, (b) irrigation expansion, and (c) afforestation conducted by three fully coupled Earth System Models (ESMs), we assess the local as well as non-local effects on heat stress and labor capacity. We found that LCLMC leads to substantial changes in temperature; however, the concomitant changes in humidity could largely diminish the combined impact on moist heat. Moreover, cropland expansion and afforestation cause inconsistent responses of day- and night-time temperature, which has strong implications for labor capacity. Across the ESMs, the results are mixed in terms of sign and magnitude. Overall, LCLMC result in non-negligible impacts on heat stress and labor capacity in low-latitude regions during the warmest seasons. In some locations, the changes of monthly average labor capacity, which are induced by the local effects of individual LCLMC options, could reach −14 and +15 percentage points. Thus, LCLMC-induced impacts on heat stress and their consequences for adaptation should be accounted for when designing LCLMC-related policies to ensure sustainable development.

KW - land cover

KW - land management

KW - heat stress

KW - labor capacity

KW - labor productivity

KW - sustainability

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DO - 10.1029/2022EF002909

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JO - Earth's Future

JF - Earth's Future

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M1 - e2022EF002909

ER -

Changes in Land Cover and Management Affect Heat Stress and Labor Capacity

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