The datasets for conducting the analysis presented here are all publicly available, including: the MODIS active fire product (https://earthdata.nasa.gov/earth-observation-data/near-real-time/firms/mcd14ml); the GOES-16 full-disk active fire product (https://registry.opendata.aws/noaa-goes/); the ERA-5 hourly climate data (https://www.ecmwf.int/en/forecasts/datasets/reanalysis-datasets/era5); the MODIS GeoMeta Collection 6.1 product (https://ladsweb.modaps.eosdis.nasa.gov/archive/geoMeta/61/); the Köppen–Geiger climate classifications (https://doi.org/10.6084/m9.figshare.6396959); and the MODIS MCD12Q1v006 Landcover Type 1 product (https://lpdaac.usgs.gov/products/mcd12q1v006/). We also generated fire perimeters using the FIRED algorithm (https://www.github.com/earthlab/firedpy) for fire events in North America and South America from May 2017 to July 2020 (https://scholar.colorado.edu/concern/datasets/d217qq78g). Source data are provided with this paper.

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Nature thanks Renata Libonati and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Peer reviewer reports are available.

Williams, A. P. et al. Observed impacts of anthropogenic climate change on wildfire in California. Earths Future 7, 892–910 (2019).

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Conceptualization, J.K.B., J.T.A., M.E.C. and A.P.W.; data curation, J.T.A., M.B.J., M.J.K. and J.M.; formal analysis, J.T.A., M.E.C., M.B.J., M.J.K. and J.M.; funding acquisition, J.K.B. and A.P.W.; investigation, J.K.B., J.T.A., M.E.C., M.B.J., M.J.K., A.L.M. and J.M.; methodology, J.K.B., J.T.A., M.E.C., M.B.J., M.J.K., J.M. and A.P.W.; project administration, J.K.B.; resources, M.B.J.; software, M.B.J., M.J.K. and J.M.; supervision, J.K.B.; visualization, J.K.B., J.T.A., M.E.C., M.B.J., M.J.K., A.L.M., J.M. and A.P.W.; writing—original draft, J.K.B., M.B.J., M.J.K. and J.M.; writing—review and editing J.K.B., J.T.A., M.E.C., M.B.J., M.J.K., A.L.M., J.M. and A.P.W.

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a, The Köppen–Geiger climate classifications69. b, The MODIS MOD12Q1 landcover68. c, Areas in red fill represent Köppen–Geiger landcover classes that were burnable (that is, ≥ 100 fire events in the FIRED data product37 that also had GOES detections19 between December 2017 and June 2020).

a–d, The average total of daytime hours (a), night-time hours (b), nights (days, 24-hour periods, when VPDmin > VPDt; c) and consecutive nights (d) per year (1991–2020) where minimum VPD > VPDt across the burnable globe. e–h, Change in annual number of daytime hours (e), night-time hours (Fig. 4 reproduced here for ease of comparison; f), nights (g) and consecutive nights (h) (1979–2019) where minimum VPD > VPDt based on a linear trend across the burnable globe.

Williamson, G. J. et al. Measurement of inter-and intra-annual variability of landscape fire activity at a continental scale: the Australian case. Environ. Res. Lett. 11, 035003 (2016).

A dashed line marks the land-cover specific VPD threshold. The red points indicate observations made during the day and the blue points represent night-time observations.

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Night-time provides a critical window for slowing or extinguishing fires owing to the lower temperature and the lower vapour pressure deficit (VPD). However, fire danger is most often assessed based on daytime conditions1,2, capturing what promotes fire spread rather than what impedes fire. Although it is well appreciated that changing daytime weather conditions are exacerbating fire, potential changes in night-time conditions—and their associated role as fire reducers—are less understood. Here we show that night-time fire intensity has increased, which is linked to hotter and drier nights. Our findings are based on global satellite observations of daytime and night-time fire detections and corresponding hourly climate data, from which we determine landcover-specific thresholds of VPD (VPDt), below which fire detections are very rare (less than 95 per cent modelled chance). Globally, daily minimum VPD increased by 25 per cent from 1979 to 2020. Across burnable lands, the annual number of flammable night-time hours—when VPD exceeds VPDt—increased by 110 hours, allowing five additional nights when flammability never ceases. Across nearly one-fifth of burnable lands, flammable nights increased by at least one week across this period. Globally, night fires have become 7.2 per cent more intense from 2003 to 2020, measured via a satellite record. These results reinforce the lack of night-time relief that wildfire suppression teams have experienced in recent years. We expect that continued night-time warming owing to anthropogenic climate change will promote more intense, longer-lasting and larger fires.

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a, b, Trends (2003–2020) in MODIS fire radiative power (MW per detection) for detections that occurred during the day and night, and areas with increases and decreases in flammable night-time hours from 1979–2020 (a) and active fire detections (per overpass per M km2) and percent of total detections that occurred at night, globally and by major Köppen–Geiger climate classification69 (Siegel-estimated slopes70 at monthly aggregations at 1°; b). Bold lines surrounded by dotted confidence intervals indicate significant trends. The underlying data are the observed values with the seasonal oscillation removed, and smoothed to aid visualization.

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The code for conducting the data integration and analysis is available at contributor and Earth Lab’s GitHub repositories, including code for: calculation of hourly VPD and the delineation of day and night hours (https://github.com/abatz/VPD) or at DOI (https://doi.org/10.5281/zenodo.5911663); quantifying monthly counts of day and night MODIS overpasses (https://github.com/mikoontz/modis-overpass-correction) or at DOI (https://doi.org/10.5281/zenodo.5911671); and the remainder of the workflow (https://github.com/earthlab/warming-weakens-the-nighttime-barrier-to-global-fire) or at DOI (https://doi.org/10.5281/zenodo.5911673). A Python software package, ‘firedpy’, recreates the FIRED event perimeters from the FIRED algorithm, available at https://github.com/earthlab/firedpy.

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Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Andela, N., Kaiser, J. W., van der Werf, G. R. & Wooster, M. J. New fire diurnal cycle characterizations to improve fire radiative energy assessments made from MODIS observations. Atmos. Chem. Phys. 15, 8831–8846 (2015).

Funding for this work was provided by Earth Lab through CU Boulder’s Grand Challenge Initiative and the Cooperative Institute for Research in Environmental Sciences (CIRES) at CU Boulder. J.K.B. was supported, in part, by the National Science Foundation’s CAREER (grant number 1846384) and Macrosystems (grant number 2017889) programmes. A.P.W. was supported by the Zegar Family Foundation. M.E.C. was supported, in part, by ‘RII Track-1: Linking Genome to Phenome to Predict Adaptive Responses of Organisms to Changing Landscapes’ under the National Science Foundation (grant number OIA-1757324).

The posterior mean is shown as a solid line, with 1,000 posterior draws as transparent lines in the background to convey uncertainty. Facets are presented in ascending order of the derived VPD thresholds.

Balch, J.K., Abatzoglou, J.T., Joseph, M.B. et al. Warming weakens the night-time barrier to global fire. Nature 602, 442–448 (2022). https://doi.org/10.1038/s41586-021-04325-1

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a–c, Day (a), night (b) and the percentage of night-time (c) detections out of total detections, Siegel-estimated slopes70 of MODIS active fire detections20 at 1° annual aggregations. Grey pixels are those defined as burnable but without a significant trend.

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Night-fire meaning

These authors contributed equally: John T. Abatzoglou, Maxwell B. Joseph, Michael J. Koontz, Adam L. Mahood, Joseph McGlinchy

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Each line, smoothed using a 31-day window, represents the expected number of day or night active fire detections per overpass per million km2 (left facets) or the expected day or night FRP per detection (right facets) for each landcover type averaged across 2003–2020. Note the y axis is on the log10 scale  and the FRP facet y axis begins at 15. Facets are presented in ascending order of the derived VPDt (Extended Data Table 2). Bimodality in the ‘peak’ is largely explained by landcover types that are split across the Northern and Southern hemispheres.

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