Our new paper, “Cities as hotspots of compound heat and fine particulate matter pollution: A 23-year urban–rural comparison across the United States“, is published in Environmental Research (IF: 7.7).

The paper can be downloaded at https://www.sciencedirect.com/science/article/abs/pii/S0013935125017608.

Authors: Jessica Leffel, Chenghao Wang, Xiao-Ming Hu, Sarah Feron, & Sarah Henry

Abstract: Heat stress and fine particulate matter (PM2.5) pollution are major stressors that threaten public health and environmental quality. When heat waves and PM2.5 pollution episodes co-occur as compound events, their impacts intensify, often leading to increased mortality and morbidity. This study provides a 23-year (2000–2022) analysis of heat waves, PM2.5 pollution episodes, and their compound occurrences during the warm season across urban and surrounding rural areas of the contiguous U.S. using reconstructed daily minimum air temperature and PM2.5 datasets. Results show that urban areas generally experienced more frequent, prolonged, and intense events than rural surroundings. Specifically, 98.8 % of cities had more frequent heat waves, 88.6 % experienced longer durations, and 98.8 % were more intense, primarily due to the nighttime urban heat island effect. Similarly, 85.4 % of cities had more frequent PM2.5 pollution episodes, 52.8 % experienced longer durations, and 80.5 % exhibited higher cumulative pollution intensity, largely driven by urban emissions. Compound heat and PM2.5 pollution episodes were more frequent and intense in ∼98 % of urban areas, with more than half experiencing longer durations. The spatial patterns of compound events closely resembled those of PM2.5 pollution episodes, suggesting that air pollution plays a dominant role in their occurrence. Notably, after a declining trend through ∼2016, the number of PM2.5 pollution and compound event days increased in the western U.S. in recent years due to rising wildfire emissions. These findings highlight the heightened environmental risks experienced by urban populations and emphasize the need for city- and region-specific heat and pollution mitigation strategies.

DOI: https://doi.org/10.1016/j.envres.2025.122508

Fig. 9. Annual frequency of (a) PM2.5 pollution episodes and (b) compound events, measured as the number of event days in urban areas across the CONUS, eastern U.S. (Northeast, Upper Midwest, Ohio Valley, and Southeast), and western U.S. (Southwest, Northwest, and West). Each box shows the interquartile range (IQR), with the horizontal line indicating the median, whiskers extending to 1.5 × IQR, and points beyond the whiskers representing outliers. The inset in (b) shows the climate regions used to define the eastern and western U.S. (blue and red, respectively).