Precipitation amount and event size interact to reduce ecosystem functioning during dry years in a mesic grassland

Felton, Andrew J.; Slette, Ingrid J.; Smith, Melinda D.; Knapp, Alan K.

doi:10.1111/gcb.14789

Cited by 73 publications

(52 citation statements)

References 76 publications

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“…Plant productivity was enhanced with increasing water availability, which is in line with the findings in previous studies (Li et al, 2003;Heisler-White et al, 2008;Fu et al, 2010). Note that more water addition could increase water losses via runoff, evaporation or deep soil water percolation (Knapp et al, 2008), and result in decreasing water resource utilization for plant productivity (Felton et al, 2019). High soil moisture can further prevent soil organic matter decomposition (Yang et al, 2002), as a result reducing production due to nutrients loss.…”

Section: Potentilla Acaulis Equationsupporting

confidence: 87%

“…Extreme drought and rainfall events are predicted to vary spatially and temporally under climate change (IPCC, 2007;Benestad et al, 2012). The range of rainfall amount impacts terrestrial ecosystems as water limits plant growth, reproduction and productivity (Koerner et al, 2014;Estiarte et al, 2016;Felton et al, 2019). Biomass is an important variable that can be applied to explore the response of plants to the changes of rainfall.…”

Section: Introductionmentioning

confidence: 99%

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Effects of Water Addition on Reproductive Allocation of Dominant Plant Species in Inner Mongolia Steppe

Liu

2020

Front. Plant Sci.

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Extreme events such as extreme drought and precipitation are expected to increase in intensity and/or duration in the face of climate change. Such changes significantly affect plant productivity and the biomass allocation between reproductive and vegetation organs (i.e., reproductive allocation). Our aims are to test the effects of water addition on the trade-offs in allocation of plant biomass and whether such effects are modified by species. A manipulative experiment was conducted from May 2000 to October 2001, where four dominant plant species (i.e., Leymus chinensis , Stipa grandis , Artemisia frigida , and Potentilla acaulis ) in the Inner Mongolia steppe in China were treated with 8 levels of water addition. Results demonstrated that water addition significantly affected the reproductive allocation of plants, and such effects were modified by species. Specifically, with increasing water availability, L. chinensis was not impacted, while A. frigida allocated more biomass to reproductive organs than to vegetative organs, while such allocation in S. grandis and P. acaulis first decreased, and then increased after reaching a peak. Our results indicated that plant species can adjust their reproductive allocation patterns to deal with water availability gradients. Climatic factors such as rainfall and temperature usually co-appearing, thus future research should explore the joint effects of several climate change factors on grasslands in order to maintain the health and sustainability of grasslands.

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Section: Potentilla Acaulis Equationsupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Effects of Water Addition on Reproductive Allocation of Dominant Plant Species in Inner Mongolia Steppe

Liu

2020

Front. Plant Sci.

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“…The increased differences in temperature between years probably contributed to the larger variability in the SOS. Second, precipitation increased until the mid‐1990s for the whole study area (Lee & Sohn, 2011), which was probably related to the significant preseason increase in precipitation across the whole study area over the study period, reducing growth sensitivity to water availability in these arid and semi‐arid regions (Felton et al., 2019; Li et al., 2019; Shen et al., 2015). As a result, phenology dynamics might have become more related to temperature and variability therein.…”

Section: Discussionmentioning

confidence: 99%

Decreasing control of precipitation on grassland spring phenology in temperate China

Xing

et al. 2020

Global Ecol. Biogeogr.

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AimVegetation phenology is highly sensitive to climate change. The timing of spring phenology in temperate grasslands is regulated primarily by temperature and precipitation. The aim of this study was to determine whether the primary factor regulating vegetation phenology has changed under ongoing climate change and the underlying mechanisms.LocationTemperate semi‐dry grasslands in China.Time period1982–2015.Major taxa studiedTemperate grassland.MethodsWe extracted start of season (SOS) dates using five standard methods from satellite‐derived normalized difference vegetation index (NDVI) data and determined the primary factor regulating spring phenology using partial correlation analysis.ResultsThe SOS date did not change significantly during the entire 1982–2015 study period in these semi‐dry grasslands, but interannual variability increased significantly from the first subperiod [1982–1998, 8.8 ± 1.1 days (mean ± SE)] to the second subperiod (1999–2015, 10.3 ± 1.1 days). Interestingly, we found that the primary factor regulating SOS shifted from precipitation during 1982–1998 to temperature during 1999–2015. Specifically, we found that during the first period, the SOS in 67.5% of the study area was determined by precipitation (mean partial correlation coefficient, r = 0.58 ± 0.16), but during the second period the main regulating factor in 75.0% of the study area was temperature (r = 0.61 ± 0.14).Main conclusionsThe change in the primary driver of spring phenology was attributed mainly to significant increases in preseason precipitation. Our study highlights that the response of spring phenology to climatic factors might change under ongoing climate change. This shift should be addressed in phenology models to simulate grassland phenology better, in addition to its impact on carbon and water cycles in future climate conditions.

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“…Conducting these experiments in ecosystem with existing long‐term PPT–NPP datasets can yield additional insights (Felton et al, 2020; Knapp et al, 2018). Long‐term data adds historical context about past responses (Knapp et al, 2020) and are all‐inclusive in terms of drivers of NPP.…”

Section: Anomaly Duration and Precipitation–productivity Relationshipsmentioning

confidence: 99%

Precipitation–productivity relationships and the duration of precipitation anomalies: An underappreciated dimension of climate change

Felton

Knapp

Smith

2020

Global Change Biology

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In terrestrial ecosystems, climate change forecasts of increased frequencies and magnitudes of wet and dry precipitation anomalies are expected to shift precipitation–net primary productivity (PPT–NPP) relationships from linear to nonlinear. Less understood, however, is how future changes in the duration of PPT anomalies will alter PPT–NPP relationships. A review of the literature shows strong potential for the duration of wet and dry PPT anomalies to impact NPP and to interact with the magnitude of anomalies. Within semi‐arid and mesic grassland ecosystems, PPT gradient experiments indicate that short‐duration (1 year) PPT anomalies are often insufficient to drive nonlinear aboveground NPP responses. But long‐term studies, within desert to forest ecosystems, demonstrate how multi‐year PPT anomalies may result in increasing impacts on NPP through time, and thus alter PPT–NPP relationships. We present a conceptual model detailing how NPP responses to PPT anomalies may amplify with the duration of an event, how responses may vary in xeric vs. mesic ecosystems, and how these differences are most likely due to demographic mechanisms. Experiments that can unravel the independent and interactive impacts of the magnitude and duration of wet and dry PPT anomalies are needed, with multi‐site long‐term PPT gradient experiments particularly well‐suited for this task.

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Precipitation amount and event size interact to reduce ecosystem functioning during dry years in a mesic grassland

Cited by 73 publications

References 76 publications

Effects of Water Addition on Reproductive Allocation of Dominant Plant Species in Inner Mongolia Steppe

Effects of Water Addition on Reproductive Allocation of Dominant Plant Species in Inner Mongolia Steppe

Decreasing control of precipitation on grassland spring phenology in temperate China

Precipitation–productivity relationships and the duration of precipitation anomalies: An underappreciated dimension of climate change

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