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RESEARCH ARTICLE (Open Access)

Fires and their key drivers in Mexico

Laura E. Montoya A B , Rogelio O. Corona-Núñez A C D and Julio E. Campo https://orcid.org/0000-0002-7595-8593 A *
+ Author Affiliations
- Author Affiliations

A Instituto de Ecología, Universidad Nacional Autónoma de México, AP 2075, Ciudad Universitaria, Coyoacán 04510, Mexico City, Mexico.

B Posgrado en Ciencias Biológicas, Universidad Nacional Autónoma de México (Posgrado en Ciencias Biológicas, Unidad de Posgrado, Edificio D, 1° Piso, Circuito de Posgrados, Ciudad Universitaria), Coyoacán 04510, CDMX, Mexico.

C Facultad de Ciencias, Universidad Nacional Autónoma de México, CU, Coyoacán 04510, Mexico City, Mexico.

D Procesos y Sistemas de Información en Geomática SA de CV, Calle 5 Viveros de Petén No. 18, Viveros del Valle, Tlalnepantla 54060, Mexico State, Mexico.

* Correspondence to: jcampo@ecologia.unam.mx

International Journal of Wildland Fire 32(5) 651-664 https://doi.org/10.1071/WF22154
Submitted: 9 July 2022  Accepted: 18 February 2023   Published: 14 March 2023

© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing on behalf of IAWF. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

Background: Despite the regional and global effects of biomass burning at national and pantropical scales, little effort has focused on determining the influence of climate and socioeconomic conditions on fire regimes in tropical regions.

Aims: We explored the climate and human factors that explain remotely sensed burnt area and fire abundance in Mexico.

Methods: We used MCD64A1 data and climate and socioeconomic metrics to understand factors explaining the variation in number of fires and burned area.

Key results: The largest burned area (41.9% of the total) occurred in temperate forests, grasslands and hydrophilic vegetation, with numerous fire events of medium relative size. The next most extensive burned area (38%) was observed in croplands, with numerous small-size fires. The third group (17.8%) occurred in tropical forests, which had the smallest and most frequent fires. Finally, a fourth group (11.9%) was composed of shrublands, which showed the largest fire sizes and lowest-frequency events. The variability of burned area was related to variations in temperature and precipitation, poverty index, altitude, and distance to water bodies.

Conclusions and Implications: Our analysis suggests that an assessment integrating climate, human and topographic metrics predicts burned area and may improve fire forecasting in Mexico landscapes.

Keywords: biomass burning, burned area, climate, fires, fire frequency, human influences, key drivers, seasonal, spatial.

Introduction

Earth Observation satellites estimate that ~4 million km2 are burned globally every year (Lizundia-Loiola et al. 2020), affecting mainly savannas and tropical dry forests (Yin et al. 2020; Zheng et al. 2021; Corona‐Núñez and Campo 2023). Changes in the total burned area have recently been observed, raising serious concerns about how they will develop in response to projected future changes in climate and land uses (Bond et al. 2005; Pausas and Ribeiro 2017; Pausas and Keeley 2021; Haas et al. 2022). Despite the regional and global-scale effects of fires on the global carbon (C) cycle and biodiversity conservation, little effort has been dedicated to understanding the influence of climate and socioeconomic conditions on fire regimes (Archibald et al. 2018; Kelley et al. 2019). Moreover, with increasing pressure on natural ecosystems from humans, global-scale studies suggest that these human factors could be among the dominant controls on fire dynamics in many regions (Haas et al. 2022; Wu et al. 2022).

Fire effects are very diverse, including on C emissions, vegetation dynamics and biodiversity and soil nutrients (Bruun et al. 2009; Lasslop et al. 2019; Pausas and Keeley 2019; McLauchlan et al. 2020; Agbeshie et al. 2022). For example, Akagi et al. (2011) estimated global emissions from biomass burning at 2.55 Pg C per year, with a tropical contribution of 1.27 Pg C (Randerson et al. 2012). Although fire is a natural factor in different ecosystems, helping to promote diversity and natural regeneration (Kelly and Brotons 2017; Archibald et al. 2018; Kelly et al. 2020), fire return intervals have been affected by human activities (Benali et al. 2017; Earl and Simmonds 2018). However, changes in the frequency and size of fires in recent decades have been also associated with exceptionally warm and dry conditions, and fire are then more probable as a result of climate change (Cochrane and Ryan 2009; Kirchmeier‐Young et al. 2019; Bowman et al. 2020; Collins et al. 2022), but their interactions with human activities are far from being comprehensively understood (Harrison et al. 2021). Although the most common factors that drive fires are climate conditions (particularly those affecting vegetation abundance and extent and intensity of water deficit as drought), contributions from demographic and socioeconomic changes, such as population growth, gross domestic product and cropland expansion play an important role in fire propagation (Archibald et al. 2009; Andela et al. 2017; Forkel et al. 2019; Corona‐Núñez and Campo 2023). The combinations of all the previous factors drive a large variability in fire characteristics, which results in the creation of mosaics of different states of ecosystem regeneration and promote environmental heterogeneity (Turner 2005; McKenzie et al. 2011; Cardinale et al. 2012). Thus, knowledge of the environmental factors driving patterns of area burned is crucial for native ecosystem conservation where changing climate and fuel management practices are likely to drive shifts in fire regimes.

It is recognised that the tropics are involved in a high proportion of the global fires, including high fire density (Chuvieco et al. 2008; Corona‐Núñez and Campo 2023). These fires are a serious ecological threat to tropical region biodiversity. For example, Mexico, with a total of 55 terrestrial ecoregions (Fig. S1), has the largest diversity of terrestrial ecoregions in the Americas and suffers a high density of fires (Corona‐Núñez et al. 2020). The long dry season from November to May in Mexican forests, grasslands and shrublands and the high rate of fuel load accumulation during this rainless period favour extensive biomass burning (Myers and Rodríguez-Trejo 2009; CONAFOR 2020), C emissions (Corona‐Núñez et al. 2020) and loss of biodiversity (Manson and Jardel Peláez 2009). Moreover, C emissions from fires in Mexico are responsible for 5% of the pantropical C emissions by fires with an significant increase in the last decade (Corona‐Núñez et al. 2020). Moreover, Mexican C emissions from fires are accelerating over the global standard, probably owing to climate change in drylands (Krawchuk et al. 2009; Pechony and Shindell 2010), as is the case of the country. For example, Corona‐Núñez et al. (2020) found that the national C fire emissions increased exceeded the global average increase in three times during. Consequently, understanding drivers of fires is a major keystone for fire-mitigation strategies, ecosystem services and biodiversity conservation in the country.

Although past studies of climate drivers of Mexican fire have focused mainly on the El Niño–Southern Oscillation (ENSO), identifying spatiotemporal heterogeneous responses in precipitation and the resulting fire activity and C emissions (Corona‐Núñez et al. 2020), limited effort has been devoted to addressing the climate drivers and human influences on fire activity due to traditional uses of fire in slash-and-burn agriculture. Motivated by these gaps in our knowledge of climate and human influences on fires in Mexico, the aims of this study are to assess the spatiotemporal variability of fires in terms of number of fires and burned area in Mexico, and provide further insights into the state of knowledge of interactions between climate and human factors on Mexican fires. For that purpose, we use gridded environmental and social data in Mexico to examine trends and environmental and social drivers of burned area and the proportion of the main ecosystems that were impacted by fires from 2001 to 2020. We focus on fires ≥0.25 km2 because they account for more than 95% of the area burnt across the country (CONAFOR 2020) and can have the greatest impact on the environment and society. Finally, this study shows the variability in drivers and severity of fires among different ecosystems, namely both tropical and temperate forests, grasslands, shrublands, croplands, and other vegetations (halophilic and hydrophilic vegetation, mangroves, riparian vegetation and coastal dune vegetation).


Materials and methods

Fire identification

We used Google Earth Engine (GEE) for fire data acquisition (Gorelick et al. 2017). The fire dataset consisted of the MCD64A1 product from MODIS (Giglio et al. 2021) included in the Earth Engine Data Catalogue in GEE. MCD64A1 returns fire boundaries with a spatial resolution of 500 m and employs MODIS surface reflectance imagery coupled with active fire observations. To address limitations of the MCD64A1 product, we tested the assumption that MCD64A1 data were representative of other fire products and not biased owing to omission errors: the distribution of MCD64A1 fire data was compared with those recorded in the field by CONAFOR (2020), and the spatial distribution was similar (similarity above 78% was observed for each year). In addition, validation of the MODIS burned area product relies mainly on the use of high-resolution Landsat scenes (Boschetti et al. 2019), and quality assurance dataset indicators discard persistent hot spots, too few training observations, or insufficient spectral separability between burned and unburned classes (Artés et al. 2019). The frequency of fire includes annual information in raster format considering 500-mburned pixels, for which the addition of raster layers was calculated by map algebra in a single layer with values from 0 (lack to fire) to 20 (at least one fire per year over the 20 years of the study period) and finally vectorised into polygons.

Almost all the fires on cropland are intentional (fire management) and even those that occur in native ecosystems are also usually attributable to humans; in >90% of cases, the fires result from human intervention (Balch et al. 2017; Bowman et al. 2020). As with the methodology used it is not possible to infer fire origin, prescribed burns and wildfires were treated without distinction. Thus, the number of fires refers to the fire events recorded every Julian day and grouped by month and year analysed. We performed a wall-to-wall monthly analysis of Mexico for the period 2001–2020. The study considers the terrestrial part of Mexico (1 932 524 km2) at 500-m spatial resolution.

We related all the fire data to Mexico’s most complete and detailed land-use/land-cover maps. These maps were developed by the National Institute of Statistics and Geography (INEGI) for the years 2002, 2005, 2009, 2015, and 2017 (INEGI 2003, 2005, 2009, 2013, 2017). All the maps were reclassified into seven land-use/cover types; these classes consisted of (i) temperate forests, (ii) tropical dry forests, (iii) tropical rainforests, (iv) shrublands, (v) grasslands, (vi) croplands, and (vii) other, which includes halophilic and hydrophilic vegetation, mangroves, riparian vegetation and coastal dune vegetation, similar classifications to others (Mendoza-Ponce et al. 2020).

Explanatory variables

To identify the main influences on fires, we related the site conditions of fires to local climate, topographic, and socioeconomic variables for each fire event (Table 1). We included a set of 32 explanatory variables (20 climatic, 5 topographic, and 7 socioeconomic variables).


Table 1.  Climatic, topographic and socioeconomic metrics selected.
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Several studies have demonstrated the utility of large-scale climatic factors for regional fire prediction (Keeley 2004; Brey et al. 2021; Wang et al. 2021), while weather conditions are usually analysed as drivers that modulate variations in ignition efficiency (Andela et al. 2017; van der Werf et al. 2017). Climatic variables such as temperature and precipitation have been recognised as key drivers of moisture availability and fire propagation (Archibald et al. 2009), and fuel moisture has long been recognised as a major component of fire danger (Dupuy et al. 2020), because components of fire activity such as number of fires or burned area are known to respond positively to increasing fuel dryness (Flannigan et al. 2009; Turco et al. 2017). To evaluate the climatic influencers, we included the 19 bioclimatic variables (Bio 1–Bio 19) taken from WorldClim (Fick and Hijmans 2017); these variables consist of 11 variables related to temperature and 8 related to precipitation, and their seasonal changes. Additionally, we evaluated water deficiency based on the Lang aridity index (Trabucco and Zomer 2019) as the ratio of mean annual precipitation and mean annual temperature (mm per °C) as precipitation and temperature alone have been shown to be inadequate to measure hydrological conditions (Quan et al. 2013). This index suggests that the rise in temperature increases water deficiency and makes the air drier.

The topographic features include altitude, slope and the Euclidian distance to water bodies and rivers. The topographic data were derived from a digital terrain model with a spatial resolution of 90 m from the Shuttle Radar Topography Mission V.2.1 (Farr et al. 2007). From it, we derived the altitude and the slope at 500-m resolution. Finally, to evaluate the influence of human activities on fires, we evaluated different socioeconomic conditions such as the Euclidian distance to protected areas (CONANP 2014), roads (Meijer et al. 2018), and human settlements. Complementarily, we used the gross domestic product, population size and social marginalisation index at the municipality level (CONAPO 2011). All the spatial information was rescaled to a common grid cell of 1 km for further analysis. Table 1 provides a summary of all the variables used in this study, as well as their sources.

Statistical analysis

We used the Wilcoxon rank‐sum test (W test) with continuity correction to test the statistical similarity between observations if the observations came from independent samples with different variances. Comparison of fire number and size and burned area across ecosystems (covers) involved one-way analysis of variance (ANOVA). We used Principal Component Analysis (PCA) to associate climatic and socioeconomic influences on the number of fires and burned area. The PCA analysis allows the dimensionality of interrelated variables to be reduced, providing insights about their interrelations, and suggesting simpler interpretations of the original data while retaining most of the variance of the original dataset (Afifi et al. 2019). However, PCA solves the multicollinearity problem by creation of the components among the original explanatory variables. PCA tests were performed with a 95% confidence level by means of the libraries raster (Hijmans et al. 2020), pcaMethods (Stacklies et al. 2007), and factoextra (Kassambara and Mundt 2020). All statistical tests were performed in R software version 3.5.2 (R Core Team 2018).


Results

Variability of fire number and burned area

The number of fires and burned area showed large variability across years (by a factor of three in the case of number of fires, and by a factor of six in the case of burned area) (Fig. 1; Tables S1, S2). The mean number of annual fire events was 12 424 ± 799 (mean ± 1 s.e.), with the lowest number registered in 2014 (5563) and the maximum in 2003 (18 617) (Fig. 1, Table S1). Fires affected a mean annual extent of 28 955 ± 2697 km2. Overall, a strong positive relationship was observed between the annual number of fires and the annual burned area (R2 = 0.71, P < 0.001) (Fig. S2). During the year 2011, after the strongest La Niña event during the study period, the largest total burned area was recorded; meanwhile, in 2015, after a weak El Niño year (2014–2015), the lowest burned area was observed.


Fig. 1.  Time series for total (a) number of fires, and (b) burned area from 2001 to 2020.
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The intra-annual variability of both the number of fires (Fig. 2a) and burned area (Fig. 2b) shows that the highest number of fires and burned areas were recorded in May (40.0 ± 2.02 and 36.0 ± 1.58% of the total annual events and annual burned area, respectively). In contrast, the lowest were recorded from August to November (accounting for 3.2 ± 0.57% of the total annual number of events, and 3.2 ± 0.64% of the annual burned area).


Fig. 2.  Boxplot of monthly (a) number of fires, and (b) burned area from 2001 to 2020. Red dots represent monthly observations for each evaluated year. Outliers are represented with grey dots. Different letters represent different clusters (P < 0.05).
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On an annual basis, there is a large variability in the number of fires and burned area among ecosystems (Fig. 3, Tables S1, S2). The largest number of fires was observed in croplands (with an annual mean of 46.8 ± 1.53% of the total number of events), followed by the forest ecosystems (i.e. tropical and temperate forests) that comprised ~44% of the total number of fire events (22.9 ± 1.08 in tropical forests and 20.6 ± 1.33% in temperate forests, respectively). Across tropical forests, tropical dry forests were more affected (59.0 ± 2.52% of the total fires in the tropical forest biome) than their humid counterpart (41.0 ± 2.47%) (P < 0.05). The remaining fire events occurred in other vegetations (i.e. halophilic and hydrophilic vegetation, mangroves, riparian vegetation and coastal dune vegetation), grasslands and shrublands (5.1 ± 0.10, 3.7 ± 0.14 and 0.8 ± 0.09%, respectively). Across native covers, the contribution of each ecosystem type to the total burned area decreased following the order temperate forests > tropical forests (tropical dry forest plus tropical rainforest) > other vegetation ≈ grassland (Fig. 3, Table S2).


Fig. 3.  Time series of the (a) total burned area from 2001 to 2020, and (b) its proportion by land cover.
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Fire sizes also show large variability among covers (Fig. 4). Small-sized fires (<1.0 km2) were the most common, and their contribution to the total burned area in each cover decreased following the order: tropical rainforests (71.6%) > tropical dry forests (68.9%) > croplands (68.8%) > temperate forests (60.3%) > grasslands (56.3%) > shrublands (50.0%) (P < 0.05). We found a decreasing gradient in the mean fire size in the direction shrublands > grasslands > temperate forests > other vegetation > tropical dry forests ≈ tropical rainforests ≈ croplands (Fig. S3, Table S3). On average, 2.7 ± 0.36% of the total temperate forest surface in the country was burned annually, 1.3 ± 0.20% of tropical dry forest, 2.2 ± 0.44% of the tropical rainforest, 0.1 ± 0.03% of shrubland, 1.0 ± 0.14% of grassland, 2.4 ± 0.20% of croplands, and 1.5 ± 0.19% of other vegetation (Fig. S4).


Fig. 4.  Frequency of fire sizes by cover: (a) temperate forest, (b) tropical dry forest, (c) tropical rainforest, (d) shrubland, (e) grassland, and (f) cropland during the period from 2001 to 2020.
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The fire return interval differed considerably across Mexico (Fig. 5). The corresponding ANOVA indicated that difference is highly significant across ecosystems (P < 0.01) and paired comparisons using the Tukey–Kramer HSD (honestly significant difference) test show that plants in shrublands consistently suffered fewer fire events (fire return interval of 8.9 ± 0.44 year), while grasslands were the most frequently perturbed by fires (return interval of 6.5 ± 0.71 year). The remaining covers (tropical rainforests, 7.9 ± 0.55 year; tropical dry forests, 7.8 ± 0.60 year; temperate forests 7.6 ± 0.61 year; and croplands, 7.2 ± 0.65 year) constituted an intermediate, statistically homogeneous group (P > 0.05). Recurrent fires dominated the Pacific Coast and the Peninsula of Yucatan (Fig. 5), where tropical dry forest is the most abundant native vegetation. In contrast, less frequent fires were recorded in the north, where shrublands are the most representative ecosystem.


Fig. 5.  Spatial distribution of fire frequencies (fire occurrence in each pixel) during the period 2001–2020. The fire frequencies varied from 0 (white, i.e. lack of fires) to 20 (at least one fire per year over the 20 years of the study period).
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Factors of fire variability

The first three principal components (PCs) account for 58.0% of the total variability of the fire dataset (Fig. 6, Table S4). The PCA showed that burned area variability was related to climate variations in temperature (annual mean in the driest and in the coldest quarters, minimum in the coldest month and maximum in the warmest month) and precipitation amount (in the wettest month and the wettest quarter, i.e. in the three consecutive months that are wetter than any other set of three consecutive months). The PCA also indicated links of burned area with human factors (e.g. poverty index), altitude and distance to water bodies.


Fig. 6.  Principal components analysis of (a) number of fires per year, (b) burned area (km2 per year), and (c) land cover data. Details for variables codes are in Table 1.
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Climatic and human drivers influence fire frequency and the size of the burned area (Fig. 6a, b, Table S4). The frequency of fire includes annual information in raster format considering 500 m burned pixels, for which the addition of raster l ayers was calculated by map algebra in a single layer with values from 0 (lack to fire) to 20 (at least one fire per year over the 20 years of the study period) and finally vectorised into polygons. Polygons of burned area with low fire frequencies (less than 5 years with fire events recorded in the study period) were affected by all analysed climate, topographic and socioeconomic factors. More frequent fires across years (that occurred 5–15 years in the study period) showed influence of both precipitation amount and distribution. Finally, recurrent fires (more than 15 years with record of fire events) were influenced by slope, distance to water bodies and distance to urban and rural localities. Regarding fire size, small to medium-sized fires (less than 50 km2) were influenced by many climate and socioeconomic factors. Larger fires (50–200 km2) were influenced by seasonality in precipitation, topographic characteristics (altitude and slope) and humans. The largest fires (≥200 km2; megafires, as in Linley et al. 2022) were influenced by ranges in annual temperature, seasonality in precipitation and topographic factors (altitude and slope).

Drivers of fires differed considerably among ecosystems (Fig. 6c, Table S4). Fires in the temperate forest were driven by temperature (isothermality), topographic (slope) and human (all analysed metrics) factors. Fire drivers differed between tropical forest ecosystems. Fires in tropical dry forests were mainly influenced by human factors (distance to urban and rural localities and to roads), whereas in tropical rainforests, they were driven by temperature (isothermality) and extreme or limiting precipitation factors (precipitation in the driest month, in the driest quarter, in the warmest quarter and in the coldest quarter). Fires in shrublands were more influenced by the amplitude of temperature (mean diurnal range, temperature seasonality), the seasonality in precipitation and population density. Fires in croplands were influenced by temperature (isothermality and seasonality), extreme precipitation factors (precipitation of driest month, precipitation seasonality, precipitation of driest quarter, precipitation of coldest quarter) and human factors, while fires in grasslands were related to human factors and climate (mean diurnal range temperature, isothermality and seasonality in precipitation).


Discussion

Variability of fires in Mexico

Most of the Mexican ecosystems experience significant water limitation, with approximately 90% of the country’s surface area experiencing an annual deficit of rainfall relative to evaporation demand (Díaz-Padilla et al. 2011), with 7 months of recurrent droughts (November to May). Correspondingly, plants experience a large period without water availability, except in the moist tropical rainforests and some areas with mountain temperate forests. Thus, the rainless period modulates both ecosystem function (Campo 2016) and C emissions by fires (Cruz-López and López-Saldaña 2011) that peak at the end of the dry season when the largest and driest wildland fuel accumulation occurs.

We show that small fires account for the largest proportion of burned area in the country. Furthermore, our data set of fire number and size (Tables S1–S3) allow us to identify four groups of burned area across ecosystems. The first, with the largest burned area (41.9% of the total burned area in the country) includes temperate forests, grasslands and hydrophilic vegetation, which show numerous fire events of relatively moderate size. The next most extensive burned area (38%) is observed in croplands, with abundant small-sized fires. A third group (17.8%) includes tropical forests (both dry forests and rainforests), with the smallest and most frequent fire events. Finally, the fourth group (11.9%) identified includes shrublands, which show the largest fire sizes and the least-frequent events. A remarkable observation from our results is the significant positive relationship of total burned area with fire frequency (Fig. S2), although a strong influence of climate was observed associated with the strongest La Niña event in 2011 when the largest burned area was recorded, suggesting a delayed positive effect of La Niña on fires probably owing to an increase in litter production. In contrast, after a weak El Niño year (2014–2015), the lowest burned area observed (year 2015 in Fig. S2) could be reflecting reduced litter accumulation. Our observations support those reported by others (Chen et al. 2017; Corona‐Núñez et al. 2020).

We found that fire return interval (i.e. the prevailing period available for vegetation regeneration between fires) was highest in water-limited shrublands and lowest in grass fuel ecosystems with fast-growing plants (grasslands). The large and persistent C density in tropical forest ecosystems (Pan et al. 2011; Campo and Merino 2016) was burned every ~8 years irrespective of precipitation regime, a fire return interval similar to those observed in temperate forests. Although fast-growing trees suggest a rapid recovery of vegetation in tropical forests after burning, fires represent a threat to biological conservation in these remarkable endemic biodiverse ecosystems (Challenger and Soberón 2008), mainly in tropical rainforests where trees lack morphological and physiological adaptations to burning (Miller and Kauffman 1998; Rosell 2016). However, despite coniferous vegetation having developed strategies to cope with fire, C losses are expected from recently burned temperate forests owing to soil erosion (Saynes et al. 2012; Santín and Doerr 2019). Because of the long period required for plant regrowth in temperate forests and more frequent fires (Corona‐Núñez et al. 2020), this ecosystem could experience a reduction of its C storage in biomass and soils. Aside from these short- and long-term scenarios, our study allows us to conclude that more forest fires without rapid recovery from natural regeneration or active restoration practices weaken the land C sink capacity in the following years.

To characterise the impact of fires across ecosystems, we estimated the fraction of vegetation cover that was burned each year. Our data indicate that the average burned surface is higher in temperate and tropical rainforests than in tropical dry forests. These results may contradict the hypothesis that the tropical dry forest biome is a fire-prone system (Corona‐Núñez and Campo 2023) and demonstrate that fire disturbance in this forest ecosystem reflects direct (Fig. 6c) and indirect human influences owing to fire management in savannas located in tropical dry landscapes with forest savanna fringes (Galvin and Reid 2010; Zheng et al. 2021; de la Peña‐Domene et al. 2022).

Drivers of fires in Mexico

Our analyses provide evidence of a climatically driven annual burned area and the proportion of native ecosystems that burnt in Mexico. Observed patterns in both fire number and burned area over the past two decades were driven primarily by extreme or limiting precipitation factors and temperature, mainly in temperate forests, tropical rainforests and grasslands. The currently identified ENSO influence, related to sea surface temperature anomalies, on the Mexican fires and burned area fraction in our study is largely consistent with previous conclusions that large fires are associated with anomalous drought (Canadell et al. 2021; Duane et al. 2021; Pausas and Keeley 2021). Drought affects the spatial connectivity of dry fine fuels and the frequency of surface weather conditions that promote rapid wildfire growth. The combination of dry fine fuels and fire weather conditions breaks down or reduces the influence of barriers to fire spread and facilitates the development of large wildfires (Nolan et al. 2016). However, prolonged and severe drought stress on plants reduces foliar moisture and increases forest canopy dieback and standing dead fuel biomass (Nolan et al. 2020; Hartmann et al. 2022). As the moisture content of canopy fuel decreases, the flammability of plant crowns increases, leading to greater flame height, and likelihood of canopy fire initiation (Molina et al. 2022). Thus, our findings indicate that if the climate becomes warmer and drier across Mexico over the coming decades (Conde et al. 2011), the exposure of native ecosystems to fires could exceed the fire resistance of vegetation (Parks and Abatzoglou 2020; Jiao et al. 2021; Collins et al. 2022). Targeted management of ecosystems aimed at increasing resistance and resilience will be required to mitigate the elevated risk of fires, as well as for the restoration of affected regions.

Our analysis suggests that human factors also drove the fires, consistent with official reports (CONAFOR 2020). Most of the land-use/land-cover changes that Mexico has experienced in the last decades involved fire as a useful tool for the elimination of vegetation (Dunbar-Irwin and Safford 2016; Rivera-Huerta et al. 2016), and socioeconomic factors such as gross domestic product and distance to rural localities were important key drivers of deforestation (Mendoza-Ponce et al. 2018). Interestingly, we estimated similar fire return intervals for temperate and tropical forest ecosystems as well as croplands. The similar return interval of fires in native vegetation and cropland probably reflect direct and indirect effects of traditional management of fires in slash-and-burn agriculture in tropical regions (Corona-Núñez et al. 2018; Mendoza-Ponce et al. 2018).

Deforestation and fires have been recognised as key factor that influences the C cycle (Houghton and Nassikas 2017; van der Werf et al. 2017). Mendoza-Ponce et al. (2018) have suggested that deforestation rates in Mexico have decreased in the last three decades, to a mean annual deforestation rate of 5027 km2. In contrast, our results indicate that burned area has not decreased between 2001 and 2020. Thus, our study suggest that fires could be affecting native ecosystems more strongly than deforestation. For example, we found that annually ~2.0% of the temperate forest and tropical rainforests areas in the country were affected by fires; these estimates are considerably greater than the forest areas affected by deforestation reported by Mendoza-Ponce et al. (2018) (by a factor of 10 in the case of temperate forests, and by a factor of 5 in the case of tropical rainforests). Despite fires affecting a smaller proportion of tropical dry forest surface, the size is the double that of those affected by deforestation (Mendoza-Ponce et al. 2018). Overall, the impacts of fires on forest ecosystems have exceeded those from deforestation, suggesting that they not only influence the C stocks and emissions but could be a key factor in biodiversity loss, particularly of endemic species.


Conclusion

In conclusion, we explored the climate and human influences on fire dynamics, an understanding that is of interest for conserving natural capital in megadiverse countries where some types of vegetation, especially tropical rainforests, are very sensitive to fires. Our study allows an understanding of fire drivers either at countrywide or biome scales. Particularly, we illustrate that climate is the most influential factor on fire occurrence in Mexico, considering both average conditions and exceptional ones. Climate affects rainfall distribution within a year, and seasonal droughts impact fuel abundance through vegetation productivity and fuel water content. However, extreme fire seasons are related to exceptional climate conditions, such as those linked to La Niña events, or a combination of heatwaves and long droughts. In the face of climate change and the expected increase in drought risk, fire impacts on terrestrial ecosystems are expected to increase in the future (IPCC 2021). Our results also show that fire characteristics such as size and frequency proved to be influenced in different ways by climate and socioeconomic conditions that drive land-use and land-cover change. Understanding fire influences may enhance land-management practices and mitigate fire environmental impacts, including C emission and species loss in rich biodiversity hotspots (Myers et al. 2000).


Supplementary material

Supplementary material is available online.


Data availability

The data that support this study will be shared on reasonable request to the corresponding author.


Conflicts of interest

The authors declare no conflicts of interest. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.


Declaration of funding

Laura E. Montoya holds a fellowship from the Mexican National Council of Science and Technology (CONACYT) Grant 382196, for her PhD studies. Rogelio O. Corona-Núñez holds a postdoctoral contract supported by the General Direction of Academic Personnel (DGAPA), Universidad Nacional Autónoma de México.


Author contributions

Conceptualisation, Rogelio O. Corona-Núñez, and Julio E. Campo; investigation, Laura E. Montoya and Rogelio O. Corona-Núñez with input from Julio E. Campo; data analysis, Laura E. Montoya and Rogelio O. Corona-Núñez; original draft preparation, Laura E. Montoya with review, editing and writing from Rogelio O. Corona-Núñez; writing – review and editing, Julio E. Campo.



Acknowledgements

This article constitutes a requisite for obtaining a PhD in Science in the Programa de Posgrado en Ciencias Biológicas (Universidad Nacional Autónoma de México) by Laura E. Montoya.


References

Afifi A, May S, Donatello RA, Clark VA (2019) ‘Practical multivariate analysis.’ (CRC Press: Florida, USA)
| Crossref |

Agbeshie AA, Abugre S, Atta-Darkwa T, Awuah R (2022) A review of the effects of forest fire on soil properties. Journal of Forestry Research 33, 1419–1441.
A review of the effects of forest fire on soil properties.Crossref | GoogleScholarGoogle Scholar |

Akagi SK, Yokelson RJ, Wiedinmyer C, Alvarado MJ, Reid JS, Karl T, Crounse JD, Wennberg PO (2011) Emission factors for open and domestic biomass burning for use in atmospheric models. Atmospheric Chemistry and Physics 11, 4039–4072.
Emission factors for open and domestic biomass burning for use in atmospheric models.Crossref | GoogleScholarGoogle Scholar |

Andela N, Morton DC, Giglio L, Chen Y, van der Werf GR, Kasibhatla PS, DeFries RS, Collatz GJ, Hantson S, Kloster S, Bachelet D, Forrest M, Lasslop G, Li F, Mangeon S, Melton JR, Yue C, Randerson JT (2017) A human-driven decline in global burned area. Science 356, 1356–1362.
A human-driven decline in global burned area.Crossref | GoogleScholarGoogle Scholar |

Archibald S, Roy DP, van Wilgen BW, Scholes RJ (2009) What limits fire? An examination of drivers of burnt area in southern Africa. Global Change Biology 15, 613–630.
What limits fire? An examination of drivers of burnt area in southern Africa.Crossref | GoogleScholarGoogle Scholar |

Archibald S, Lehmann CER, Belcher CM, Bond WJ, Bradstock RA, Daniau A-L, Dexter KG, Forrestel EJ, Greve M, He T, Higgins SI, Hoffmann WA, Lamont BB, McGlinn DJ, Moncrieff GR, Osborne CP, Pausas JG, Price O, Ripley BS, Rogers BM, Schwilk DW, Simon MF, Turetsky MR, van der Werf GR, Zanne AE (2018) Biological and geophysical feedbacks with fire in the Earth system. Environmental Research Letters 13, 033003
Biological and geophysical feedbacks with fire in the Earth system.Crossref | GoogleScholarGoogle Scholar |

Artés T, Oom D, de Rigo D, Durrant TH, Maianti P, Libertà G, San-Miguel-Ayanz J (2019) A global wildfire dataset for the analysis of fire regimes and fire behaviour. Scientific Data 6, 296
A global wildfire dataset for the analysis of fire regimes and fire behaviour.Crossref | GoogleScholarGoogle Scholar |

Balch JK, Bradley BA, Abatzoglou JT, Nagy RC, Fusco EJ, Mahood AL (2017) Human-started wildfires expand the fire niche across the United States. Proceedings of the National Academy of Sciences 114, 2946–2951.
Human-started wildfires expand the fire niche across the United States.Crossref | GoogleScholarGoogle Scholar |

Benali A, Mota B, Carvalhais N, Oom D, Miller LM, Campagnolo ML, Pereira JMC (2017) Bimodal fire regimes unveil a global-scale anthropogenic fingerprint. Global Ecology and Biogeography 26, 799–811.
Bimodal fire regimes unveil a global-scale anthropogenic fingerprint.Crossref | GoogleScholarGoogle Scholar |

Bond WJ, Woodward FI, Midgley GF (2005) The global distribution of ecosystems in a world without fire. New Phytologist 165, 525–538.
The global distribution of ecosystems in a world without fire.Crossref | GoogleScholarGoogle Scholar |

Boschetti L, Roy DP, Giglio L, Huang H, Zubkova M, Humber ML (2019) Global validation of the Collection 6 MODIS burned area product. Remote Sensing of Environment 235, 111490
Global validation of the Collection 6 MODIS burned area product.Crossref | GoogleScholarGoogle Scholar |

Bowman DMJS, Kolden CA, Abatzoglou JT, Johnston FH, van der Werf GR, Flannigan M (2020) Vegetation fires in the Anthropocene. Nature Reviews Earth & Environment 1, 500–515.
Vegetation fires in the Anthropocene.Crossref | GoogleScholarGoogle Scholar |

Brey SJ, Barnes EA, Pierce JR, Swann ALS, Fischer EV (2021) Past variance and future projections of the environmental conditions driving western US summertime wildfire burn area. Earth’s Future 9, e2020EF001645
Past variance and future projections of the environmental conditions driving western US summertime wildfire burn area.Crossref | GoogleScholarGoogle Scholar |

Bruun TB, de Neergaard A, Lawrence D, Ziegler AD (2009) Environmental consequences of the demise in swidden cultivation in Southeast Asia: carbon storage and soil quality. Human Ecology 37, 375–388.
Environmental consequences of the demise in swidden cultivation in Southeast Asia: carbon storage and soil quality.Crossref | GoogleScholarGoogle Scholar |

Campo J (2016) Shift from ecosystem P to N limitation at precipitation gradient in tropical dry forests at Yucatan, Mexico. Environmental Research Letters 11, 095006
Shift from ecosystem P to N limitation at precipitation gradient in tropical dry forests at Yucatan, Mexico.Crossref | GoogleScholarGoogle Scholar |

Campo J, Merino A (2016) Variations in soil carbon sequestration and their determinants along a precipitation gradient in seasonally dry tropical forest ecosystems. Global Change Biology 22, 1942–1956.
Variations in soil carbon sequestration and their determinants along a precipitation gradient in seasonally dry tropical forest ecosystems.Crossref | GoogleScholarGoogle Scholar |

Canadell JG, Meyer CP, Cook GD, Dowdy A, Briggs PR, Knauer J, Pepler A, Haverd V (2021) Multi-decadal increase of forest burned area in Australia is linked to climate change. Nature Communications 12, 6921
Multi-decadal increase of forest burned area in Australia is linked to climate change.Crossref | GoogleScholarGoogle Scholar |

Cardinale BJ, Duffy JE, Gonzalez A, Hooper DU, Perrings C, Venail P, Narwani A, Mace GM, Tilman D, Wardle DA, Kinzig AP, Daily GC, Loreau M, Grace JB, Larigauderie A, Srivastava DS, Naeem S (2012) Biodiversity loss and its impact on humanity. Nature 486, 59–67.
Biodiversity loss and its impact on humanity.Crossref | GoogleScholarGoogle Scholar |

Challenger A, Soberón J (2008) Los ecosistemas terrestres. In ‘Capital natural de México, Vol. I: conocimiento actual de la biodiversidad’. (Ed. J Sarukhán) pp. 87–108. (CONABIO: Mexico) [In Spanish]

Chen Y, Morton DC, Andela N, van der Werf GR, Giglio L, Randerson JT (2017) A pan-tropical cascade of fire driven by El Niño/Southern Oscillation. Nature Climate Change 7, 906–911.
A pan-tropical cascade of fire driven by El Niño/Southern Oscillation.Crossref | GoogleScholarGoogle Scholar |

Chuvieco E, Giglio L, Justice C (2008) Global characterization of fire activity: toward defining fire regimes from earth observation data. Global Change Biology 14, 1488–1502.
Global characterization of fire activity: toward defining fire regimes from earth observation data.Crossref | GoogleScholarGoogle Scholar |

Cochrane MA, Ryan KC (2009) Fire and fire ecology: Concepts and principles. In ‘Tropical fire ecology’. (Ed. MA Cochrane) pp. 25–62. (Springer: Berlin)
| Crossref |

Collins L, Clarke H, Clarke MF, McColl Gausden SC, Nolan RH, Penman T, Bradstock R, Varner M (2022) Warmer and drier conditions have increased the potential for large and severe fire seasons across south‐eastern Australia. Global Ecology and Biogeography 31, 1933–1948.
Warmer and drier conditions have increased the potential for large and severe fire seasons across south‐eastern Australia.Crossref | GoogleScholarGoogle Scholar |

CONAFOR (2020) ‘Reporte nacional de incendios forestales.’ (Jalisco) https://www.gob.mx/cms/uploads/attachment/file/604834/Cierre_de_la_Temporada_2020.PDF [In Spanish]

CONANP (2014) Áreas Naturales Protegidas de México. Serie cartográfica Escala 1:100 000 [Dataset]. Comisión Nacional de Áreas Naturales Protegidas. (CONAFOR: Mexico City) [In Spanish]

CONAPO (2011) Índices de marginación por entidad federativa y municipio, 2010 [Dataset]. Consejo Nacional de Población. Available at http://www.conapo.gob.mx/publicaciones/indice2010.html [In Spanish]

Conde C, Estrada F, Martínez-López B, Sanchez O, Gay Garcia C (2011) Regional climate change scenarios for México. Atmosfera 24, 125–140.

Corona‐Núñez RO, Campo JE (2023) Climate and socioeconomic drivers of biomass burning and carbon emissions from fires in tropical dry forests: a pantropical analysis. Global Change Biology 29, 1062–1079.
Climate and socioeconomic drivers of biomass burning and carbon emissions from fires in tropical dry forests: a pantropical analysis.Crossref | GoogleScholarGoogle Scholar |

Corona-Núñez RO, Campo J, Williams M (2018) Aboveground carbon storage in tropical dry forest plots in Oaxaca, Mexico. Forest Ecology and Management 409, 202–214.
Aboveground carbon storage in tropical dry forest plots in Oaxaca, Mexico.Crossref | GoogleScholarGoogle Scholar |

Corona‐Núñez RO, Li F, Campo JE (2020) Fires represent an important source of carbon emissions in Mexico. Global Biogeochemical Cycles 34, e2020GB006815
Fires represent an important source of carbon emissions in Mexico.Crossref | GoogleScholarGoogle Scholar |

Cruz-López M, López-Saldaña G (2011) Assessment of affected areas by forest fires in Mexico. In ‘Advances in remote sensing and GIS applications in forest fire management from local to global assessments’. (Eds Ayanz J, Gitas I, Camia A, Oliveira S) pp. 81–86. (European Commission: STRESA)

de la Peña‐Domene M, Tapia GR, Mesa‐Sierra N, Rivero‐Villar A, Giardina CP, Johnson NG, Campo J, Gillespie T (2022) Climatic and edaphic‐based predictors of normalized difference vegetation index in tropical dry landscapes: a pantropical analysis. Global Ecology and Biogeography 31, 1850–1863.
Climatic and edaphic‐based predictors of normalized difference vegetation index in tropical dry landscapes: a pantropical analysis.Crossref | GoogleScholarGoogle Scholar |

Díaz-Padilla G, Sánchez-Cohen I, Guajardo-Panes RA, del Ángel-Pérez AL, Ruíz-Corral A, Medina-García G, Ibarra-Castillo D (2011) Mapping of the aridity index and its population distribution in Mexico. Revista Chapingo Serie Ciencias Forestales y Del Ambiente 17, 267–275.
Mapping of the aridity index and its population distribution in Mexico.Crossref | GoogleScholarGoogle Scholar |

Duane A, Castellnou M, Brotons L (2021) Towards a comprehensive look at global drivers of novel extreme wildfire events. Climatic Change 165, 43
Towards a comprehensive look at global drivers of novel extreme wildfire events.Crossref | GoogleScholarGoogle Scholar |

Dunbar-Irwin M, Safford H (2016) Climatic and structural comparison of yellow pine and mixed-conifer forests in northern Baja California (México) and the eastern Sierra Nevada (California, USA). Forest Ecology and Management 363, 252–266.
Climatic and structural comparison of yellow pine and mixed-conifer forests in northern Baja California (México) and the eastern Sierra Nevada (California, USA).Crossref | GoogleScholarGoogle Scholar |

Dupuy J, Fargeon H, Martin-StPaul N, Pimont F, Ruffault J, Guijarro M, Hernando C, Madrigal J, Fernandes P (2020) Climate change impact on future wildfire danger and activity in southern Europe: a review. Annals of Forest Science 77, 35
Climate change impact on future wildfire danger and activity in southern Europe: a review.Crossref | GoogleScholarGoogle Scholar |

Earl N, Simmonds I (2018) Spatial and temporal variability and trends in 2001–2016 global fire activity. Journal of Geophysical Research: Atmospheres 123, 2524–2536.
Spatial and temporal variability and trends in 2001–2016 global fire activity.Crossref | GoogleScholarGoogle Scholar |

Farr TG, Rosen PA, Caro E, Crippen R, Duren R, Hensley S, Kobrick M, Paller M, Rodriguez E, Roth L, Seal D, Shaffer S, Shimada J, Umland J, Werner M, Oskin M, Burbank D, Alsdorf D (2007) The Shuttle Radar Topography Mission. Reviews of Geophysics 45, RG2004
The Shuttle Radar Topography Mission.Crossref | GoogleScholarGoogle Scholar |

Fick SE, Hijmans RJ (2017) WorldClim 2: new 1‐km spatial resolution climate surfaces for global land areas. International Journal of Climatology 37, 4302–4315.
WorldClim 2: new 1‐km spatial resolution climate surfaces for global land areas.Crossref | GoogleScholarGoogle Scholar |

Flannigan MD, Krawchuk MA, de Groot WJ, Wotton BM, Gowman LM (2009) Implications of changing climate for global wildland fire. International Journal of Wildland Fire 18, 483–507.
Implications of changing climate for global wildland fire.Crossref | GoogleScholarGoogle Scholar |

Forkel M, Dorigo W, Lasslop G, Chuvieco E, Hantson S, Heil A, Teubner I, Thonicke K, Harrison SP (2019) Recent global and regional trends in burned area and their compensating environmental controls. Environmental Research Communications 1, 051005
Recent global and regional trends in burned area and their compensating environmental controls.Crossref | GoogleScholarGoogle Scholar |

Galvin KA, Reid RS (2010) People in savanna ecosystems: land use, change, and sustainability. In ‘Ecosystem function in savannas: measurement and modeling at landscape to global scales’. (Eds MJ Hill, NP Hanan) pp. 481–495. (CRC Press: Boca Raton, FL, USA)
| Crossref |

Giglio L, Justice C, Boschetti L, Roy D (2021) MCD64A1 MODIS/Terra+Aqua Burned Area Monthly L3 Global 500m SIN Grid V006 [Data set]. NASA EOSDIS Land Processes DAAC. https://lpdaac.usgs.gov/products/mcd64a1v006/

Gorelick N, Hancher M, Dixon M, Ilyushchenko S, Thau D, Moore R (2017) Google earth engine: planetary-scale geospatial analysis for everyone. Remote Sensing of Environment 202, 18–27.
Google earth engine: planetary-scale geospatial analysis for everyone.Crossref | GoogleScholarGoogle Scholar |

Haas O, Prentice IC, Harrison SP (2022) Global environmental controls on wildfire burnt area, size, and intensity. Environmental Research Letters 17, 065004
Global environmental controls on wildfire burnt area, size, and intensity.Crossref | GoogleScholarGoogle Scholar |

Harrison SP, Prentice IC, Bloomfield KJ, Dong N, Forkel M, Forrest M, Ningthoujam RK, Pellegrini A, Shen Y, Baudena M, Cardoso AW, Huss JC, Joshi J, Oliveras I, Pausas JG, Simpson KJ (2021) Understanding and modelling wildfire regimes: an ecological perspective. Environmental Research Letters 16, 125008
Understanding and modelling wildfire regimes: an ecological perspective.Crossref | GoogleScholarGoogle Scholar |

Hartmann H, Bastos A, Das AJ, Esquivel-Muelbert A, Hammond WM, Martínez-Vilalta J, McDowell NG, Powers JS, Pugh TAM, Ruthrof KX, Allen CD (2022) Climate change risks to global forest health: emergence of unexpected events of elevated tree mortality worldwide. Annual Review of Plant Biology 73, 673–702.
Climate change risks to global forest health: emergence of unexpected events of elevated tree mortality worldwide.Crossref | GoogleScholarGoogle Scholar |

Hijmans RJ, van Etten J, Sumner M, Cheng J, Baston D, Bevan A, Bivand R, Busetto L, Canty M, Fasoli B, Forrest D, Ghosh A, Golicher D, Gray J, Greenberg JA, Hiemstra P, Hingee K, Ilich A, Karney C, Mattiuzzi M, Mosher S, Naimi B, Nowosad J, Pebesma E, Lamigueiro OP, Racine EB, Rowlingson B, Shortridge A, Venables B, Wueest R (2020) Package ‘raster’, Geographic Data Analysis and Modeling. Available at https://CRAN.R-project.org/package=raster

Houghton RA, Nassikas AA (2017) Global and regional fluxes of carbon from land use and land cover change 1850–2015. Global Biogeochemical Cycles 31, 456–472.
Global and regional fluxes of carbon from land use and land cover change 1850–2015.Crossref | GoogleScholarGoogle Scholar |

INEGI (2003) Conjunto de datos vectoriales de la carta de uso del suelo y vegetación. Escala: 1:1000000. Serie II. Continuo Nacional [Dataset]. Instituto Nacional de Estadística, Geografía e Informática. Available at https://www.inegi.org.mx/app/biblioteca/ficha.html?upc=702825267865 [In Spanish]

INEGI (2005) Conjunto de datos vectoriales de la carta de uso del suelo y vegetación. Escala 1:250000. Serie III. Continuo Nacional [Dataset]. Instituto Nacional de Estadística, Geografía e Informática. Available at https://www.inegi.org.mx/app/biblioteca/ficha.html?upc=702825007022 [In Spanish]

INEGI (2009) Conjunto de datos vectoriales de la carta de uso del suelo y vegetación. Escala 1:250000. Serie IV. Conjunto Nacional [Dataset]. Instituto Nacional de Estadística, Geografía e Informática. [In Spanish]

INEGI (2013) Conjunto de datos vectoriales de la carta de uso del suelo y vegetación. Escala 1:250000. Serie V. Conjunto Nacional [Dataset]. Instituto Nacional de Estadística, Geografía e Informática. Available at https://www.inegi.org.mx/app/biblioteca/ficha.html?upc=702825007024 [In Spanish]

INEGI (2017) Conjunto de datos vectoriales de la carta de uso del suelo y vegetación. Escala 1:250 000. Serie VI. Conjunto Nacional [Dataset]. Instituto Nacional de Estadística, Geografía e Informática. Available at https://www.inegi.org.mx/app/biblioteca/ficha.html?upc=889463598459https://www.inegi.org.mx/app/biblioteca/ficha.html?upc=889463598459 [In Spanish]

IPCC (2021) Climate change 2021: Synthesis report. In ‘Contribution of working groups I, II and III to the sixth assessment report of the Intergovernmental Panel on Climate Change’. (Eds V Malsson‐Delmonte, P Zhai, A Pirani, et al.) (Cambridge: Geneva)

Jiao T, Williams CA, de Kauwe MG, Schwalm CR, Medlyn BE (2021) Patterns of post‐drought recovery are strongly influenced by drought duration, frequency, post‐drought wetness, and bioclimatic setting. Global Change Biology 27, 4630–4643.
Patterns of post‐drought recovery are strongly influenced by drought duration, frequency, post‐drought wetness, and bioclimatic setting.Crossref | GoogleScholarGoogle Scholar |

Kassambara A, Mundt F (2020) Factoextra: extract and visualize the results of multivariate data analyses. Available at https://CRAN.R-project.org/package=factoextra

Keeley JE (2004) Impact of antecedent climate on fire regimes in coastal California. International Journal of Wildland Fire 13, 173–182.
Impact of antecedent climate on fire regimes in coastal California.Crossref | GoogleScholarGoogle Scholar |

Kelley DI, Bistinas I, Whitley R, Burton C, Marthews TR, Dong N (2019) How contemporary bioclimatic and human controls change global fire regimes. Nature Climate Change 9, 690–696.
How contemporary bioclimatic and human controls change global fire regimes.Crossref | GoogleScholarGoogle Scholar |

Kelly LT, Brotons L (2017) Using fire to promote biodiversity. Science 355, 1264–1265.
Using fire to promote biodiversity.Crossref | GoogleScholarGoogle Scholar |

Kelly LT, Giljohann KM, Duane A, Aquilué N, Archibald S, Batllori E, Bennett AF, Buckland ST, Canelles Q, Clarke MF, Fortin M-J, Hermoso V, Herrando S, Keane RE, Lake FK, McCarthy MA, Morán-Ordóñez A, Parr CL, Pausas JG, Penman TD, Regos A, Rumpff L, Santos JL, Smith AL, Syphard AD, Tingley MW, Brotons L (2020) Fire and biodiversity in the Anthropocene. Science 370, eabb0355
Fire and biodiversity in the Anthropocene.Crossref | GoogleScholarGoogle Scholar |

Kirchmeier‐Young MC, Gillett NP, Zwiers FW, Cannon AJ, Anslow FS (2019) Attribution of the influence of human‐induced climate change on an extreme fire season. Earth’s Future 7, 2–10.
Attribution of the influence of human‐induced climate change on an extreme fire season.Crossref | GoogleScholarGoogle Scholar |

Krawchuk MA, Moritz MA, Parisien M-A, van Dorn J, Hayhoe K (2009) Global pyrogeography: the current and future distribution of wildfire. PLoS One 4, e5102
Global pyrogeography: the current and future distribution of wildfire.Crossref | GoogleScholarGoogle Scholar |

Lasslop G, Coppola AI, Voulgarakis A, Yue C, Veraverbeke S (2019) Influence of fire on the carbon cycle and climate. Current Climate Change Reports 5, 112–123.
Influence of fire on the carbon cycle and climate.Crossref | GoogleScholarGoogle Scholar |

Linley GD, Jolly CJ, Doherty TS, Geary WL, Armenteras D, Belcher CM, Bliege Bird R, Duane A, Fletcher M-S, Giorgis MA, Haslem A, Jones GM, Kelly LT, Lee CKF, Nolan RH, Parr CL, Pausas JG, Price JN, Regos A, Ritchie EG, Ruffault J, Williamson GJ, Wu Q, Nimmo DG, Poulter B (2022) What do you mean, ‘megafire’? Global Ecology and Biogeography 31, 1906–1922.
What do you mean, ‘megafire’?Crossref | GoogleScholarGoogle Scholar |

Lizundia-Loiola J, Otón G, Ramo R, Chuvieco E (2020) A spatio-temporal active-fire clustering approach for global burned area mapping at 250 m from MODIS data. Remote Sensing of Environment 236, 111493
A spatio-temporal active-fire clustering approach for global burned area mapping at 250 m from MODIS data.Crossref | GoogleScholarGoogle Scholar |

Manson RH, Jardel Peláez EJ (2009) Perturbaciones y desatres naturales: impactos sobre las ecorregiones, la biodiversidad y el bienestar socioeconómico. In ‘Capital natural de México, Vol. I: conocimiento actual de la biodiversidad’. (Ed. J Sarukhán) pp. 131–184. (CONABIO: Mexico) [In Spanish]

McKenzie D, Miller C, Falk DA (2011) ‘The landscape ecology of fire.’ (Springer: Amsterdam)
| Crossref |

McLauchlan KK, Higuera PE, Miesel J, Rogers BM, Schweitzer J, Shuman JK, Tepley AJ, Varner JM, Veblen TT, Adalsteinsson SA, Balch JK, Baker P, Batllori E, Bigio E, Brando P, Cattau M, Chipman ML, Coen J, Crandall R, Daniels L, Enright N, Gross WS, Harvey BJ, Hatten JA, Hermann S, Hewitt RE, Kobziar LN, Landesmann JB, Loranty MM, Maezumi SY, Mearns L, Moritz M, Myers JA, Pausas JG, Pellegrini AFA, Platt WJ, Roozeboom J, Safford H, Santos F, Scheller RM, Sherriff RL, Smith KG, Smith MD, Watts AC (2020) Fire as a fundamental ecological process: research advances and frontiers. Journal of Ecology 108, 2047–2069.
Fire as a fundamental ecological process: research advances and frontiers.Crossref | GoogleScholarGoogle Scholar |

Meijer JR, Huijbregts MAJ, Schotten KCGJ, Schipper AM (2018) Global patterns of current and future road infrastructure. Environmental Research Letters 13, 064006
Global patterns of current and future road infrastructure.Crossref | GoogleScholarGoogle Scholar |

Mendoza-Ponce A, Corona-Núñez R, Kraxner F, Leduc S, Patrizio P (2018) Identifying effects of land use cover changes and climate change on terrestrial ecosystems and carbon stocks in Mexico. Global Environmental Change 53, 12–23.
Identifying effects of land use cover changes and climate change on terrestrial ecosystems and carbon stocks in Mexico.Crossref | GoogleScholarGoogle Scholar |

Mendoza-Ponce AV, Corona-Núñez RO, Kraxner F, Estrada F (2020) Spatial prioritization for biodiversity conservation in a megadiverse country. Anthropocene 32, 100267
Spatial prioritization for biodiversity conservation in a megadiverse country.Crossref | GoogleScholarGoogle Scholar |

Miller PM, Kauffman JB (1998) Seedling and sprout response to slash-and-burn agriculture in a tropical deciduous forest. Biotropica 30, 538–546.
Seedling and sprout response to slash-and-burn agriculture in a tropical deciduous forest.Crossref | GoogleScholarGoogle Scholar |

Molina JR, Ortega M, Rodríguez y Silva F (2022) Scorch height and volume modeling in prescribed fires: effects of canopy gaps in Pinus pinaster stands in southern Europe. Forest Ecology and Management 506, 119979
Scorch height and volume modeling in prescribed fires: effects of canopy gaps in Pinus pinaster stands in southern Europe.Crossref | GoogleScholarGoogle Scholar |

Myers N, Mittermeier RA, Mittermeier CG, da Fonseca GAB, Kent J (2000) Biodiversity hotspots for conservation priorities. Nature 403, 853–858.
Biodiversity hotspots for conservation priorities.Crossref | GoogleScholarGoogle Scholar |

Myers RL, Rodríguez-Trejo DA (2009) Fire in tropical pine ecosystems. In ‘Tropical fire ecology: climate change, land use, and ecosystem dynamics’. (Ed. MA Cochrane) pp. 557–605. (Springer: Berlin)

Nolan RH, Boer MM, Resco de Dios V, Caccamo G, Bradstock RA (2016) Large-scale, dynamic transformations in fuel moisture drive wildfire activity across southeastern Australia. Geophysical Research Letters 43, 4229–4238.
Large-scale, dynamic transformations in fuel moisture drive wildfire activity across southeastern Australia.Crossref | GoogleScholarGoogle Scholar |

Nolan RH, Blackman CJ, de Dios VR, Choat B, Medlyn BE, Li X, Bradstock RA, Boer MM (2020) Linking forest flammability and plant vulnerability to drought. Forests 11, 779
Linking forest flammability and plant vulnerability to drought.Crossref | GoogleScholarGoogle Scholar |

Pan Y, Birdsey RA, Fang J, Houghton R, Kauppi PE, Kurz WA, Phillips OL, Shvidenko A, Lewis SL, Canadell JG, Ciais P, Jackson RB, Pacala SW, McGuire AD, Piao S, Rautiainen A, Sitch S, Hayes D (2011) A large and persistent carbon sink in the World’s forests. Science 333, 988–993.
A large and persistent carbon sink in the World’s forests.Crossref | GoogleScholarGoogle Scholar |

Parks SA, Abatzoglou JT (2020) Warmer and drier fire seasons contribute to increases in area burned at high severity in western US forests from 1985 to 2017. Geophysical Research Letters 47, e2020GL089858
Warmer and drier fire seasons contribute to increases in area burned at high severity in western US forests from 1985 to 2017.Crossref | GoogleScholarGoogle Scholar |

Pausas JG, Keeley JE (2019) Wildfires as an ecosystem service. Frontiers in Ecology and the Environment 17, 289–295.
Wildfires as an ecosystem service.Crossref | GoogleScholarGoogle Scholar |

Pausas JG, Keeley JE (2021) Wildfires and global change. Frontiers in Ecology and the Environment 19, 387–395.
Wildfires and global change.Crossref | GoogleScholarGoogle Scholar |

Pausas JG, Ribeiro E (2017) Fire and plant diversity at the global scale. Global Ecology and Biogeography 26, 889–897.
Fire and plant diversity at the global scale.Crossref | GoogleScholarGoogle Scholar |

Pechony O, Shindell DT (2010) Driving forces of global wildfires over the past millennium and the forthcoming century. Proceedings of the National Academy of Sciences 107, 19167–19170.
Driving forces of global wildfires over the past millennium and the forthcoming century.Crossref | GoogleScholarGoogle Scholar |

Quan C, Han S, Utescher T, Zhang C, Liu Y-S (Christopher) (2013) Validation of temperature–precipitation based aridity index: Paleoclimatic implications. Palaeogeography, Palaeoclimatology, Palaeoecology 386, 86–95.
Validation of temperature–precipitation based aridity index: Paleoclimatic implications.Crossref | GoogleScholarGoogle Scholar |

Randerson JT, Chen Y, van der Werf GR, Rogers BM, Morton DC (2012) Global burned area and biomass burning emissions from small fires. Journal of Geophysical Research: Biogeosciences 117, G04012
Global burned area and biomass burning emissions from small fires.Crossref | GoogleScholarGoogle Scholar |

R Core Team (2018) R: a language and environment for statistical computing. Available at https://www.R-project.org/

Rivera-Huerta H, Safford HD, Miller JD (2016) Patterns and trends in burned area and fire severity from 1984 to 2010 in the Sierra de San Pedro Mártir, Baja California, Mexico. Fire Ecology 12, 52–72.
Patterns and trends in burned area and fire severity from 1984 to 2010 in the Sierra de San Pedro Mártir, Baja California, Mexico.Crossref | GoogleScholarGoogle Scholar |

Rosell JA (2016) Bark thickness across the angiosperms: more than just fire. New Phytologist 211, 90–102.
Bark thickness across the angiosperms: more than just fire.Crossref | GoogleScholarGoogle Scholar |

Santín C, Doerr S (2019) Carbon. In ‘Fire effects on soil properties’. (Eds P Pereira, J Mataix-Solera, X Úbeda, G Rein, A Cerdà) pp. 115–128. (CSIRO Publishing: Melbourne, Vic., Australia)

Saynes V, Etchevers JD, Galicia L, Hidalgo C, Campo J (2012) Soil carbon dynamics in high-elevation temperate forests of Oaxaca (Mexico): thinning and rainfall effects. Bosque (Valdivia) 33, 3–11.
Soil carbon dynamics in high-elevation temperate forests of Oaxaca (Mexico): thinning and rainfall effects.Crossref | GoogleScholarGoogle Scholar |

Stacklies W, Redestig H, Scholz M, Walther D, Selbig J (2007) pcaMethods – a bioconductor package providing PCA methods for incomplete data. Bioinformatics 23, 1164–1167.
pcaMethods – a bioconductor package providing PCA methods for incomplete data.Crossref | GoogleScholarGoogle Scholar |

Trabucco A, Zomer R (2019) Global aridity index and potential evapotranspiration (ET0) climate database v2. figshare.
| Crossref |

Turco M, von Hardenberg J, AghaKouchak A, Llasat MC, Provenzale A, Trigo RM (2017) On the key role of droughts in the dynamics of summer fires in Mediterranean Europe. Scientific Reports 7, 81
On the key role of droughts in the dynamics of summer fires in Mediterranean Europe.Crossref | GoogleScholarGoogle Scholar |

Turner MG (2005) Landscape ecology: what is the state of the science. Annual Review of Ecology, Evolution, and Systematics 36, 319–344.
Landscape ecology: what is the state of the science.Crossref | GoogleScholarGoogle Scholar |

van der Werf GR, Randerson JT, Giglio L, van Leeuwen TT, Chen Y, Rogers BM, Mu M, van Marle MJE, Morton DC, Collatz GJ, Yokelson RJ, Kasibhatla PS (2017) Global fire emissions estimates during 1997–2016. Earth System Science Data 9, 697–720.
Global fire emissions estimates during 1997–2016.Crossref | GoogleScholarGoogle Scholar |

Wang SS-C, Qian Y, Leung LR, Zhang Y (2021) Identifying key drivers of wildfires in the contiguous US using machine learning and game theory interpretation. Earth’s Future 9, e2020EF001910
Identifying key drivers of wildfires in the contiguous US using machine learning and game theory interpretation.Crossref | GoogleScholarGoogle Scholar |

Wu C, Sitch S, Huntingford C, Mercado LM, Venevsky S, Lasslop G, Archibald S, Staver AC (2022) Reduced global fire activity due to human demography slows global warming by enhanced land carbon uptake. Proceedings of the National Academy of Sciences 119, e2101186119
Reduced global fire activity due to human demography slows global warming by enhanced land carbon uptake.Crossref | GoogleScholarGoogle Scholar |

Yin Y, Bloom AA, Worden J, Saatchi S, Yang Y, Williams M, Liu J, Jiang Z, Worden H, Bowman K, Frankenberg C, Schimel D (2020) Fire decline in dry tropical ecosystems enhances decadal land carbon sink. Nature Communications 11, 1900
Fire decline in dry tropical ecosystems enhances decadal land carbon sink.Crossref | GoogleScholarGoogle Scholar |

Zheng B, Ciais P, Chevallier F, Chuvieco E, Chen Y, Yang H (2021) Increasing forest fire emissions despite the decline in global burned area. Science Advances 7, eabh2646
Increasing forest fire emissions despite the decline in global burned area.Crossref | GoogleScholarGoogle Scholar |