Soil and stand structure explain shrub mortality patterns following global change–type drought and extreme precipitation

Renne, Rachel R.; Schlaepfer, Daniel R.; Palmquist, Kyle A.; Bradford, John B.; Burke, Ingrid C.; Lauenroth, William K.

doi:10.1002/ecy.2889

Cited by 34 publications

(38 citation statements)

References 60 publications

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“…Our results indicate substantial potential for rapidly increasing hot‐dry stress, particularly in the northern portions of these drylands. Stressful combinations of high temperature and low soil moisture have been shown to drive mortality of trees (Breshears et al, 2018), and may also apply to other plants (Renne et al, 2019). Our results reinforce other studies anticipating the importance of increasing heat stress for dryland plants (McDowell et al, 2016), and our focus on periods of co‐occurring extreme heat and low soil moisture provides new perspectives about patterns in future hot‐dry stress.…”

Section: Discussionmentioning

confidence: 99%

“…Barcharts show the proportion of each ecoregion with robust signal (>90% of models agreeing) of positive or negative changes in monthly SWA under the four future scenarios (colors consistent with lines) Our results indicate substantial potential for rapidly increasing hot-dry stress, particularly in the northern portions of these drylands. Stressful combinations of high temperature and low soil moisture have been shown to drive mortality of trees (Breshears et al, 2018), and may also apply to other plants (Renne et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…Dryland ecosystems are tightly linked to water availability, so future shifts in overall aridity may substantially alter dryland plant communities and the ecosystem services they provide (Bestelmeyer et al, 2015; Reynolds et al, 2007). Vegetation dynamics in dryland regions are driven primarily by availability of soil moisture, which shapes the structure and function of plant communities by affecting photosynthesis, biomass production, plant mortality, and regeneration dynamics (Gremer, Bradford, Munson, & Duniway, 2015; Renne et al, 2019; Schlaepfer et al, 2015; Shriver et al, 2018; Thoma, Munson, & Witwicki, 2018; Witwicki, Munson, & Thoma, 2016). Drought stress can leave ecosystems vulnerable to rapid species turnover and altered structure by reducing plant growth and regeneration.…”

Section: Introductionmentioning

confidence: 99%

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Robust ecological drought projections for drylands in the 21st century

Bradford

Schlaepfer

Lauenroth

et al. 2020

Global Change Biology

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Dryland ecosystems may be especially vulnerable to expected 21st century increases in temperature and aridity because they are tightly controlled by moisture availability. However, climate impact assessments in drylands are difficult because ecological dynamics are dictated by drought conditions that are difficult to define and complex to estimate from climate conditions alone. In addition, precipitation projections vary substantially among climate models, enhancing variation in overall trajectories for aridity. Here, we constrain this uncertainty by utilizing an ecosystem water balance model to quantify drought conditions with recognized ecological importance, and by identifying changes in ecological drought conditions that are robust among climate models, defined here as when >90% of models agree in the direction of change. Despite limited evidence for robust changes in precipitation, changes in ecological drought are robust over large portions of drylands in the United States and Canada. Our results suggest strong regional differences in long‐term drought trajectories, epitomized by chronic drought increases in southern areas, notably the Upper Gila Mountains and South‐Central Semi‐arid Prairies, and decreases in the north, particularly portions of the Temperate and West‐Central Semi‐arid Prairies. However, we also found that exposure to hot‐dry stress is increasing faster than mean annual temperature over most of these drylands, and those increases are greatest in northern areas. Robust shifts in seasonal drought are most apparent during the cool season; when soil water availability is projected to increase in northern regions and decrease in southern regions. The implications of these robust drought trajectories for ecosystems will vary geographically, and these results provide useful insights about the impact of climate change on these dryland ecosystems. More broadly, this approach of identifying robust changes in ecological drought may be useful for other assessments of climate impacts in drylands and provide a more rigorous foundation for making long‐term strategic resource management decisions.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Robust ecological drought projections for drylands in the 21st century

Bradford

Schlaepfer

Lauenroth

et al. 2020

Global Change Biology

Self Cite

130

101

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“…A frequently overlooked determinant of ecosystem hydrology is the rock component, including bedrock features (Schwinning, 2010; Dawson et al ., 2020). Several studies investigating forest responses to drought were focused on habitats with relatively deep soils that contribute to the largest share of water available to plants over the growing season (Elliott & Swank, 1994; Fensham & Fairfax, 1997; Renne et al ., 2019). However, large portions of terrestrial habitats are dominated by forests on shallow soils overlaying substrates that strongly limit root growth and water storage.…”

Section: Introductionmentioning

confidence: 99%

Water ‘on the rocks’: a summer drink for thirsty trees?

et al. 2020

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Drought-induced tree mortality frequently occurs in patches with different spatial and temporal distributions, which is only partly explained by inter-and intraspecific variation in drought tolerance. We investigated whether bedrock properties, with special reference to rock water storage capacity, affects tree water status and drought response in a rock-dominated landscape. We measured primary porosity and available water content of breccia (B) and dolostone (D) rocks. Saplings of Fraxinus ornus were grown in pots filled with soil or soil mixed with B and D rocks, and subjected to an experimental drought. Finally, we measured seasonal changes in water status of trees in field sites overlying B or D bedrock. B rocks were more porous and stored more available water than D rocks. Potted saplings grown with D rocks had less biomass and suffered more severe water stress than those with B rocks. Trees in sites with B bedrock had more favourable water status than those on D bedrock which also suffered drought-induced canopy dieback. Bedrock represents an important water source for plants under drought. Different bedrock features translate into contrasting below-ground water availability, leading to landscape-level heterogeneity of the impact of drought on tree water status and dieback.

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“…For example, severe drought events can cause dryland plant mortality and decrease productivity in surviving individuals during subsequent years (Bigler et al, 2007;Bradford and Bell, 2017). At the other extreme, unusual wet conditions can interact with soil and stand characteristics to contribute to dryland plant mortality (Renne et al, 2019) as well as facilitate regeneration of perennial plants (Shriver et al, 2018), a notoriously episodic process (Schlaepfer et al, 2014;Petrie et al, 2016). Because the frequency and severity of extreme events can influence an ecosystem's composition, structure and susceptibility to biological invaders (Bradley et al, 2010;Reichstein et al, 2013;Ummenhofer and Meehl, 2017), incorporating metrics that represent ecologically relevant extreme drought conditions may improve assessments of resistance to invasion.…”

Section: Implications For Assessing Resilience and Resistancementioning

confidence: 99%

Climate-Driven Shifts in Soil Temperature and Moisture Regimes Suggest Opportunities to Enhance Assessments of Dryland Resilience and Resistance

et al. 2019

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Assessing landscape patterns in climate vulnerability, as well as resilience and resistance to drought, disturbance, and invasive species, requires appropriate metrics of relevant environmental conditions. In dryland systems of western North America, soil temperature and moisture regimes have been widely utilized as an indicator of resilience to disturbance and resistance to invasive plant species by providing integrative indicators of long-term site aridity, which relates to ecosystem recovery potential and climatic suitability to invaders. However, the impact of climate change on these regimes, and the suitability of the indicator for estimating resistance and resilience in the context of climate change have not been assessed. Here we utilized a daily time-step, process-based, ecosystem water balance model to characterize current and future patterns in soil temperature and moisture conditions in dryland areas of western North America, and evaluate the impact of these changes on estimation of resilience and resistance. Soil temperature increases in the twenty-first century are substantial, relatively uniform geographically, and robust across climate models. Higher temperatures will expand the areas of mesic and thermic soil temperature regimes while decreasing the area of cryic and frigid temperature conditions. Projections for future precipitation are more variable both geographically and among climate models. Nevertheless, future soil moisture conditions are relatively consistent across climate models for much of the region. Projections of drier soils are expected in most of Arizona and New Mexico, as well as the central and southern U.S. Great Plains. By contrast, areas with projections of increasing soil moisture include northeastern Montana, southern Alberta and Saskatchewan, and many areas dominated by big sagebrush, particularly the Central and Northern Basin and Range and the Wyoming Basin ecoregions. Bradford et al. Enhancing Dryland Resilience and Resistance Assessments In addition, many areas dominated by big sagebrush are expected to experience pronounced shifts toward cool season moisture, which will create more area with xeric moisture conditions and less area with ustic conditions. In addition to indicating widespread geographic shifts in the distribution of soil temperature and moisture regimes, our results suggest opportunities for enhancing the integration of these conditions into a quantitative framework for assessing climate change impacts on dryland ecosystem resilience and resistance that is responsive to long-term projections.

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Soil and stand structure explain shrub mortality patterns following global change–type drought and extreme precipitation

Cited by 34 publications

References 60 publications

Robust ecological drought projections for drylands in the 21st century

Robust ecological drought projections for drylands in the 21st century

Water ‘on the rocks’: a summer drink for thirsty trees?

Climate-Driven Shifts in Soil Temperature and Moisture Regimes Suggest Opportunities to Enhance Assessments of Dryland Resilience and Resistance

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