How extreme is extreme? Demographic approaches inform the occurrence and ecological relevance of extreme events

Latimer, Christopher E.; Zuckerberg, Benjamin

doi:10.1002/ecm.1385

Cited by 20 publications

(17 citation statements)

References 89 publications

(224 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although extreme weather events are increasing in frequency throughout the year (Rahmstorf and Coumou 2011), extreme weather during winter may leave wildlife exceptionally vulnerable as many species are already living at the razor's edge – operating with scarce food resources and temperatures often at the lower end of their thermal limits (Salewski et al 2013, Penczykowski et al 2017, Casson et al 2019). Several types of winter weather events have the potential to impact northerly ecosystems and their dependent species – disrupting behavior, distributions and survival – despite lasting only days (Martin 2017, Birgander et al 2018, Kreyling et al 2019, Latimer and Zuckerberg 2019). For instance, the intrusion of the polar vortex into central and eastern North America during winter has become more common and intense as arctic warming has destabilized the jet stream separating arctic and temperate air masses, resulting in extremely cold air outbreaks in temperate areas sustained over several days to a week (Cohen et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Extreme winter weather disrupts bird occurrence and abundance patterns at geographic scales

2021

Self Cite

View full text Add to dashboard Cite

Extreme weather events are increasing in frequency and intensity as a result of modern climate change. During winter, species may be especially vulnerable to extreme weather as they are surviving on scarce resources and living at the edge of their thermal limits. We compiled data from eBird, a global citizen science initiative, to examine how 41 eastern North American birds shifted their occurrence and abundance patterns immediately following two recent extreme weather events each affecting > 2 million km2, the intrusion of a polar vortex and a winter heat wave. eBird data is continuously collected at high spatiotemporal resolution across large spatial extents, allowing us to compare species' responses immediately before and after these extreme events with trends in other winters across geographic scales. Overall, we found that birds responded differently to each extreme weather event. Bird occurrence rates did not change following the polar vortex, but where species occurred, population density was temporarily reduced, suggesting reductions in number of individuals driven by decreases in behavioral activity or temporary movement out of the area. However, birds demonstrated widespread increases in occurrence and increases in density and number of individuals where they occurred for at least 20 days after the heat wave, hinting at longer‐term range changes. Smaller‐bodied, warm‐adapted passerines tended to be most sensitive to extreme weather and responded most negatively to the polar vortex and most positively to the heat wave, while larger‐bodied, cold‐adapted waterbirds expressed only mild responses to either event. Thus, certain species may be exceptionally sensitive to extreme weather events while others are less sensitive. As climate change progresses and climatic variability increases, researchers and managers must better quantify the broad‐scale sensitivity of different species to multiple types of extreme weather events.

show abstract

Section: Introductionmentioning

confidence: 99%

Extreme winter weather disrupts bird occurrence and abundance patterns at geographic scales

2021

Self Cite

View full text Add to dashboard Cite

show abstract

“…Assessments of ECEs and their impacts are generally conducted by performing perturbation experiments (e.g., Bokhorst et al 2008;Pansch et al 2018) or by opportunistically taking advantage of a rare event (e.g., Smith 2011;Grant et al 2017;Latimer & Zuckerberg 2019). The latter type often concentrate on a single population and relatively small spatial scales or lack longterm ecological monitoring of the system prior to the ECE (but see Thibault & Brown 2008;Campbell-Staton et al 2017).…”

Section: Introductionmentioning

confidence: 99%

The effect of summer drought on the predictability of local extinctions in a butterfly metapopulation

Bergen

Dallas

DiLeo

et al. 2020

Conservation Biology

View full text Add to dashboard Cite

The ecological impacts of extreme climatic events on population dynamics and community composition are profound and predominantly negative. Using extensive data of an ecological model system, we tested whether predictions from ecological models remain robust when environmental conditions are outside the bounds of observation. We observed a 10-fold demographic decline of the Glanville fritillary butterfly (Melitaea cinxia) metapopulation on the Åland islands, Finland in the summer of 2018 and used climatic and satellite data to demonstrate that this year was an anomaly with low climatic water balance values and low vegetation productivity indices across Åland. Population growth rates were strongly associated with spatiotemporal variation in climatic water balance. Covariates shown previously to affect the extinction probability of local populations in this metapopulation were less informative when populations were exposed to severe drought during the summer months. Our results highlight the unpredictable responses of natural populations to extreme climatic events.

show abstract

“…This de nition is useful for categorizing extreme events in a climatespeci c setting. In attempting to explore the biological effects of extreme climate events, however, it is becoming increasingly important to de ne extreme events in a more setting-and organism-speci c context [14,15] . For example, Gutschick and BassiriRad [16] de ne an extreme event as one that exceeds the acclimatory capacity of an organism, while Bailey and van de Pol [17] consider an episode to be extreme when the climate or the conditions trigger a negative threshold-dependent biological response.…”

Section: Introductionmentioning

confidence: 99%

“…In other words, once a climate event is deemed extreme, we must further consider the conditions of the event in terms of an organism's biological capacity to tolerate it [15] . Extreme climate events have elicited various biological responses, including reduced body condition, shifts in species distributions, changes in functional community structure and community dynamics, and mass mortality events [14,18−20] .…”

Section: Introductionmentioning

confidence: 99%

Shooting blanks: extreme climate event promotes phenological mismatch between sexes in hibernating ground squirrels

Kucheravy

Waterman

Anjos

et al. 2021

Preprint

View full text Add to dashboard Cite

Hibernating ground squirrels rely on a short active period for breeding and mass accrual, and are thus vulnerable to extreme climate events that affect key periods in their annual cycle. Here, we observed how a heatwave in March 2012 led to a phenological mismatch between sexes in Richardson’s ground squirrels (Urocitellus richardsonii). Females emerged from hibernation and commenced breeding earlier in 2012 relative to average female emergence. Despite external indicators suggesting that males were prepared for breeding, it appeared that not all males were physiologically prepared since 58.6% of males had non-motile sperm when breeding commenced. We found that males with non-motile sperm had smaller accessory glands than males with motile sperm. Body condition, relative testes size, and the relative size of accessory glands were significant predictors of sperm motility. There was no difference in litter size among years, nor a decrease in the number of juveniles emerged in 2012 or female yearlings recruited in 2013. The impact of this heatwave on male ground squirrels emphasizes the importance of assessing the consequences of climate change on breeding success of hibernating species in both sexes, since the different cues for emergence led to a mismatch in timing under this event.

show abstract

How extreme is extreme? Demographic approaches inform the occurrence and ecological relevance of extreme events

Cited by 20 publications

References 89 publications

Extreme winter weather disrupts bird occurrence and abundance patterns at geographic scales

Extreme winter weather disrupts bird occurrence and abundance patterns at geographic scales

The effect of summer drought on the predictability of local extinctions in a butterfly metapopulation

Shooting blanks: extreme climate event promotes phenological mismatch between sexes in hibernating ground squirrels

Contact Info

Product

Resources

About