Grazing alters the sensitivity of plant productivity to precipitation in northern temperate grasslands

Batbaatar, Amgaa; Bork, Edward W.; Broadbent, Tanner; Alexander, Mike J.; Cahill, James; Carlyle, Cameron N.

doi:10.1111/jvs.13008

Cited by 17 publications

(12 citation statements)

References 61 publications

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“…For example, we observed the following patterns of response to drought in this experiment: immediate changes in soil moisture content, followed by shifts in species composition (though not richness or evenness), but inconsistent effects on ANPP. This may chiefly be through variation in the abundance of graminoids, which contribute most to the stability of productivity to precipitation in the region (Batbaatar et al, 2021;Bork et al, 2019). The positive link between the effects of reduced precipitation on species composition and evenness further suggests that changes in the abundance of graminoids may have led to differences in species composition between the ambient and reduced precipitation treatments.…”

Section: Discussionmentioning

confidence: 99%

Multi‐year drought alters plant species composition more than productivity across northern temperate grasslands

et al. 2021

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1. The occurrence of multi-year drought is predicted to increase globally with climate change. However, it is unclear whether drought effects on ecosystems are progressive through time.2. Here, we experimentally reduced growing season precipitation (GSP) by 45% at seven North American temperate grasslands for four consecutive years to determine the following: (a) whether the effects of reduced precipitation on plant community structure and biomass components (shoot, root, litter) are compounding over time; (b) whether prior year climatic and soil conditions influence subsequent drought impacts on plant community structure and biomass components; and (c) whether the effects of reduced precipitation on individual ecosystem components are related to one another.3. Across the seven field sites, we observed neither consistent nor progressive effects of reduced precipitation on any biomass component during the experiment, despite having extreme drought conditions imposed for four consecutive years.Relative to the ambient treatment, above-ground net primary productivity (ANPP) declined in response to drought during the early years of the experiment but increased above the ambient treatment in the fourth year, while root and litter biomass were stable across the sites throughout the study. Similarly, graminoid cover decreased initially but recovered by the final year of the experiment, contributing to observed differences in species composition between treatments across sites.Compositional changes were not associated with any declines in species richness or evenness. Divergent responses among years were not driven by lag effects based on prior year climatic and soil conditions. Furthermore, precipitation effects on ecosystem components were largely independent as we found only two positive links: between ANPP and plant species richness, and between species evenness and composition. 4. Synthesis. Overall, our results suggest that these northern grasslands are relatively resistant to short-term multi-year drought in the context of supporting plant diversity and biomass production.

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Section: Discussionmentioning

confidence: 99%

Multi‐year drought alters plant species composition more than productivity across northern temperate grasslands

et al. 2021

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“…For example, only a few thousand of over a million records in the evergreen forest land cover type were within fire perimeters. In addition to fire, grazing can also lead to possible phenological impacts through changes in composition, productivity, and sensitivity to precipitation variability (Fuhlendorf and Engle, 2001;Briske et al, 2005;Beever et al, 2008;Batbaatar et al, 2021). Data for grazing intensity do not exist at the scale of our study, but this metric should be considered in future assessments.…”

Section: Further Study and Limitationsmentioning

confidence: 96%

Antecedent climatic conditions spanning several years influence multiple land-surface phenology events in semi-arid environments

et al. 2022

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Ecological processes are complex, often exhibiting non-linear, interactive, or hierarchical relationships. Furthermore, models identifying drivers of phenology are constrained by uncertainty regarding predictors, interactions across scales, and legacy impacts of prior climate conditions. Nonetheless, measuring and modeling ecosystem processes such as phenology remains critical for management of ecological systems and the social systems they support. We used random forest models to assess which combination of climate, location, edaphic, vegetation composition, and disturbance variables best predict several phenological responses in three dominant land cover types in the U.S. Northwestern Great Plains (NWP). We derived phenological measures from the 25-year series of AVHRR satellite data and characterized climatic predictors (i.e., multiple moisture and/or temperature based variables) over seasonal and annual timeframes within the current year and up to 4 years prior. We found that antecedent conditions, from seasons to years before the current, were strongly associated with phenological measures, apparently mediating the responses of communities to current-year conditions. For example, at least one measure of antecedent-moisture availability [precipitation or vapor pressure deficit (VPD)] over multiple years was a key predictor of all productivity measures. Variables including longer-term lags or prior year sums, such as multi-year-cumulative moisture conditions of maximum VPD, were top predictors for start of season. Productivity measures were also associated with contextual variables such as soil characteristics and vegetation composition. Phenology is a key process that profoundly affects organism-environment relationships, spatio-temporal patterns in ecosystem structure and function, and other ecosystem dynamics. Phenology, however, is complex, and is mediated by lagged effects, interactions, and a diversity of potential drivers; nonetheless, the incorporation of antecedent conditions and contextual variables can improve models of phenology.

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“…This notion is consistent with a hypothesis that montane grassland photosynthesis is resilient to late‐season snow events and can quickly re‐establish previous function after melt, much in the same way that grass photosynthesis tends to re‐establish quickly following harvesting (Novick et al., 2004; Stoy et al., 2008), grazing (Parsons et al., 1983), and heat waves (Hoover et al., 2014). Alternately, canopy photosynthesis in mountain meadows could simply be resistant to snow disturbances following a growing body of cold‐season research that demonstrates that photosynthesis can occur under snow (Lundell et al., 2008; Starr & Oberbauer, 2003; Street et al., 2012) and the notion that grass productivity is resistant to minor disturbances like mild drought (Batbaatar et al., 2021). In this scenario, ecosystem carbon uptake would not meaningfully differ before and after snow events and ecosystem carbon uptake would have little response to snow apart from the limitations to photosynthesis caused by cold conditions and diminished light availability under the snowpack.…”

Section: Introductionmentioning

confidence: 99%

Ecosystem Gross Primary Productivity After Autumn Snowfall and Melt Events in a Mountain Meadow

et al. 2022

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Vegetation productivity is increasing in the U.S. Northern Great Plains but decreasing in some nearby Northern Rocky Mountain grasslands due to increases in aridity. It is unclear if decreases to montane grassland productivity from drying autumns can be partly offset by late‐season green‐ups after precipitation events. These include the multiple snowfall and snowmelt periods that often characterize the summer‐to‐winter transition, but are difficult to observe due to logistical constraints. Here, we quantify changes to vegetation indices and ecosystem carbon uptake that occurs after snowfall and melt in climatological autumn in a montane grassland in Montana, USA using eddy covariance, phenological camera, and remote sensing analyses. Carbon dioxide flux follows a diurnal pattern after autumn snowmelt events despite overall ecosystem C loss, suggesting that post‐snowmelt photosynthesis helps dampen C loss during autumn and provides fresh photosynthate to support ecosystem functioning. Light‐saturated photosynthesis after three snow events was not statistically different than before snowfall (∼6 μmol CO2 m−2 s−1 in 2016 and ∼2.5 μmol CO2 m−2 s−1 in 2017). Observations are consistent with the notion that canopy photosynthesis is resistant, rather than resilient, to autumn snow. MODIS indicates that post‐snow greenups can occur, but not every year. Such events likely play a small role in the annual ecosystem carbon balance but may be disproportionately important for organisms faced with dwindling late‐season forage. Future efforts should seek to understand the community and ecosystem consequences of vegetation functioning during autumn as part of an expanded effort to understand phenological changes during this under‐studied and changing time of year.

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Grazing alters the sensitivity of plant productivity to precipitation in northern temperate grasslands

Cited by 17 publications

References 61 publications

Multi‐year drought alters plant species composition more than productivity across northern temperate grasslands

Multi‐year drought alters plant species composition more than productivity across northern temperate grasslands

Antecedent climatic conditions spanning several years influence multiple land-surface phenology events in semi-arid environments

Ecosystem Gross Primary Productivity After Autumn Snowfall and Melt Events in a Mountain Meadow

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