Projected effects of climate change across many ecosystems globally include more frequent disturbance by fire and reduced plant growth due to warmer (and especially drier) conditions. Such changes affect species–particularly fire-intolerant woody plants–by simultaneously reducing recruitment, growth, and survival. Collectively, these mechanisms may narrow the fire interval window compatible with population persistence, driving species to extirpation or extinction. We present a conceptual model of these combined effects, based on synthesis of the known impacts of climate change and altered fire regimes on plant demography, and describe a syndrome we term “interval squeeze”. This model predicts that interval squeeze will increase woody plant ...
Changing disturbance-climate interactions will drive shifts in plant communities: these effects are ...
Most species face multiple anthropogenic disruptions. Few studies have quantified the cumulative inf...
Across plant communities worldwide, fire regimes reflect a combination of climatic factors and plant...
Projected effects of climate change across many ecosystems globally include more frequent disturbanc...
Climate change projections predict that Mediterranean-type ecosystems (MTEs) are becoming hotter and...
Mediterranean-type ecosystems (MTEs) harbor an exceptionally high biodiversity of vascular plants. A...
Extreme fire seasons in both hemispheres in 2019 and 2020 have highlighted the strong link between c...
Record-breaking fire seasons in many regions across the globe raise important questions about plant ...
Climate change is increasing the frequency, intensity, and size of fire events due to longer and mor...
Understanding species responses to climate change is a topic of increasing concern given climate cha...
Interval squeeze: altered fire regimes and demographic responses interact to threaten woody species ...
Altered fire regimes resulting from climate change and human activity threaten many terrestrial ecos...
Altered fire regimes resulting from climate change and human activity threaten many terrestrial ecos...
Climatic fire danger will likely increase because more droughts and heat-waves are caused by climate...
The frequency of ecological disturbances, such as fires, is changing due to changing land use and cl...
Changing disturbance-climate interactions will drive shifts in plant communities: these effects are ...
Most species face multiple anthropogenic disruptions. Few studies have quantified the cumulative inf...
Across plant communities worldwide, fire regimes reflect a combination of climatic factors and plant...
Projected effects of climate change across many ecosystems globally include more frequent disturbanc...
Climate change projections predict that Mediterranean-type ecosystems (MTEs) are becoming hotter and...
Mediterranean-type ecosystems (MTEs) harbor an exceptionally high biodiversity of vascular plants. A...
Extreme fire seasons in both hemispheres in 2019 and 2020 have highlighted the strong link between c...
Record-breaking fire seasons in many regions across the globe raise important questions about plant ...
Climate change is increasing the frequency, intensity, and size of fire events due to longer and mor...
Understanding species responses to climate change is a topic of increasing concern given climate cha...
Interval squeeze: altered fire regimes and demographic responses interact to threaten woody species ...
Altered fire regimes resulting from climate change and human activity threaten many terrestrial ecos...
Altered fire regimes resulting from climate change and human activity threaten many terrestrial ecos...
Climatic fire danger will likely increase because more droughts and heat-waves are caused by climate...
The frequency of ecological disturbances, such as fires, is changing due to changing land use and cl...
Changing disturbance-climate interactions will drive shifts in plant communities: these effects are ...
Most species face multiple anthropogenic disruptions. Few studies have quantified the cumulative inf...
Across plant communities worldwide, fire regimes reflect a combination of climatic factors and plant...