Global urban vegetation exhibits divergent thermal effects: From cooling to warming as aridity increases

Guo, Zhengfei; Esperon-Rodriguez, Manuel; Davin, Édouard L.; Huang, Heng; Chen, Bin; Hejazi, Mohamad; Wu, Jin; Wang, Jian; Ge, Yunfeng; Song, Guangqin; Zhao, Yingyi; Feng, Kuishuang; Lin, Chen; Gong, Peng; Zhou, Yuyu

doi:10.1126/sciadv.aea9165

articleScience AdvancesJan 2, 2026GOLD OA

Global urban vegetation exhibits divergent thermal effects: From cooling to warming as aridity increases

ZGZhengfei GuoMEManuel Esperon-RodriguezÉLÉdouard L. DavinHHHeng HuangBCBin Chen

University of Hong Kong · Western Sydney University · +8 more institutions

PubMed

Indexed incrossrefdoajpubmed

Abstract

Urban vegetation, a key nature-based solution for mitigating heat stress, is critical as global warming, and urban heat islands amplify high temperatures in cities, affecting over half the global population. Yet, its potential warming effects remain unquantified globally, with mechanisms unclear. Using high-resolution satellite and climate data, we provide the first global assessment of vegetation's temperature regulation across 761 megacities across 105 countries, uncovering a paradox: cooling weakens in arid environments; and in 22% of cities with

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Authors

15

ZG
Zhengfei Guo
University of Hong Kong
ME
Manuel Esperon-Rodriguez
Western Sydney University
ÉL
Édouard L. Davin
University of Bern, Oeschger Centre for Climate Change Research, Swiss Academy of Sciences
HH
Heng Huang
Sun Yat-sen University
BC
Bin Chen
University of Hong Kong

Topics & keywords

Topics

Keywords

Evapotranspiration
Urban heat island
Arid
Albedo (alchemy)
Megacity
Global warming
Vegetation (pathology)
Climate change

UN Sustainable Development Goals

Climate action

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