Abstract
Increased exposure to extreme heat from both climate change and the urban heat island effect—total urban warming—threatens the sustainability of rapidly growing urban settlements worldwide. Extreme heat exposure is highly unequal and severely impacts the urban poor. While previous studies have quantified global exposure to extreme heat, the lack of a globally accurate, fine-resolution temporal analysis of urban exposure crucially limits our ability to deploy adaptations. Here, we estimate daily urban population exposure to extreme heat for 13,115 urban settlements from 1983 to 2016. We harmonize global, fine-resolution (0.05°), daily temperature maxima and relative humidity estimates with geolocated and longitudinal global urban population data. We measure the average annual rate of increase in exposure (person-days/year−1) at the global, regional, national, and municipality levels, separating the contribution to exposure trajectories from urban population growth versus total urban warming. Using a daily maximum wet bulb globe temperature threshold of 30 °C, global exposure increased nearly 200% from 1983 to 2016. Total urban warming elevated the annual increase in exposure by 52% compared to urban population growth alone. Exposure trajectories increased for 46% of urban settlements, which together in 2016 comprised 23% of the planet’s population (1.7 billion people). However, how total urban warming and population growth drove exposure trajectories is spatially heterogeneous. This study reinforces the importance of employing multiple extreme heat exposure metrics to identify local patterns and compare exposure trends across geographies. Our results suggest that previous research underestimates extreme heat exposure, highlighting the urgency for targeted adaptations and early warning systems to reduce harm from urban extreme heat exposure.
| Original language | English (US) |
|---|---|
| Article number | e2024792118 |
| Journal | Proceedings of the National Academy of Sciences of the United States of America |
| Volume | 118 |
| Issue number | 41 |
| DOIs | |
| State | Published - Oct 12 2021 |
Bibliographical note
Funding Information:ACKNOWLEDGMENTS. We would like to thank Prof. Susan Cassels for providing an internal review of this manuscript and the Earth Research Institute computing staff for their tireless assistance throughout this project. We also thank two anonymous reviewers, guest editor, and NAS board member for their excellent feedback. C.T. was supported by the University of California Presidential Dissertation Year Fellowship through UC Santa Barbara and the Earth Institute Postdoctoral Fellowship Program, Columbia University. C.T., K.C., and T.E. received support from NSF Awards SES-1801251 and SES-1832393. K.C. and T.E. recieved support from NSF Award DEB-1924309. Support for C.F. and P.P. came from the NASA Global Precipitation Measurement mission Grant 80NSSC19K0686, the US Agency for International Development cooperative agreement 72DFFP19CA00001, and the Famine Early Warning Systems Network and the Defense Advanced Research Projects Agency World Modelers Program under Army Research Office prime contract No. W911NF-18-1-0018.
Publisher Copyright:
© 2021 National Academy of Sciences. All rights reserved.
Keywords
- Climate change
- Hazards
- Public health
- Sustainability
- Urbanization
