Nutrient identity modifies the destabilising effects of eutrophication in grasslands

Carroll, Oliver; Batzer, Evan; Bharath, Siddharth; Borer, Elizabeth T.; Campana, Sofía; Esch, Ellen H.; Hautier, Yann; Ohlert, Timothy; Seabloom, Eric W.; Adler, Peter B.; Bakker, Jonathan D.; Biederman, Lori A.; Bugalho, Miguel N.; Caldeira, Maria C.; Chen, Qingqing; Davies, Kendi F.; Fay, Philip A.; Knops, Johannes M. H.; Komatsu, Kimberly J.; Martina, Jason P.; McCann, Kevin S.; Moore, Joslin L.; Morgan, John; Muraina, Taofeek O.; Osborne, Brooke B.; Risch, Anita C.; Wilfahrt, Peter A.; Yahdjian, Laura; MacDougall, Andrew S.

doi:10.1111/ele.13946

Cited by 22 publications

(35 citation statements)

References 79 publications

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“…Addition of NPK +µ reduced the relative distribution of C and N in MAOM versus POM (fMAOM-C and -N) as compared to the control and P, respectively. These findings align with previous NutNet work that suggests grassland biomass production is co-limited by N, P, and K, as adding these together increases aboveground plant growth (Fay et al 2015;Carroll et al 2021), as we also found in our sites (Supplementary Fig. 3).…”

Section: Biogeochemistry 1supporting

confidence: 93%

Impacts of nutrient addition on soil carbon and nitrogen stoichiometry and stability in globally-distributed grasslands

et al. 2022

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Section: Biogeochemistry 1supporting

confidence: 93%

Impacts of nutrient addition on soil carbon and nitrogen stoichiometry and stability in globally-distributed grasslands

et al. 2022

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“…Plant communities on infertile soils often exhibit resource‐conservative functional traits, which may limit their responses to climate change (Fernandez‐Going et al, 2012). Conversely, they may also be more vulnerable to climate variation once nutrient limitations are relieved under eutrophication (Carroll et al, 2022). At present, the response of the stability of plant communities to various global changes along a soil fertility gradient and the underlying mechanisms remain unelucidated.…”

Section: Introductionmentioning

confidence: 99%

“…climate, soil properties, treatment intensity and duration) affect the responses of grassland stability? To address these questions, we test three interrelated hypotheses: (1) nutrient addition would decrease the temporal stability of grasslands by lessening nutrient limitations (Bai et al, 2010; Carroll et al, 2022); (2) both plant species richness (Hautier et al, 2015) and dominant plant functional group (Mackie et al, 2019; Shi et al, 2016) would play an important role in regulating stability responses to global changes and (3) community stability would be less affected by global changes in grasslands with lower soil fertility (Fernandez‐Going et al, 2012), higher climate variability (Ciemer et al, 2019), with low intensity treatments and with treatments that occurred only over short durations.…”

Section: Introductionmentioning

confidence: 99%

Multiple global changes drive grassland productivity and stability: A meta‐analysis

Zhao

et al. 2022

Journal of Ecology

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1. Temporal stability of primary productivity is the key to stable provisioning of ecosystem services to human beings. Yet, the effects of various global changes on grassland stability remain ambiguous.2. Here, we conducted a comprehensive meta-analysis based on 1070 multi-year paired observations from 173 studies, to examine the impacts of various global changes on productivity, community stability and plant diversity of grasslands on a global scale. The global change drivers include nitrogen (N) addition, phosphorus (P) addition, N and P addition, precipitation increase, precipitation decrease, elevated CO 2 and warming.3. Global change drivers generally had stronger impacts on grassland productivity than on temporal stability, except for precipitation changes. Community temporal stability was reduced by N addition, N and P addition and precipitation decrease, but was increased by precipitation increase and remained unchanged under P addition, elevated CO 2 and warming. In addition, species richness decreased under N addition, N and P addition and precipitation decrease. At the plant functional group level, N and P addition reduced grasses' stability and precipitation increase enhanced forbs' stability.4. Nutrient additions decreased community stability via increasing the inter-annual variation more than the mean of primary productivity, while precipitation changes mainly affected community temporal stability via changing mean productivity. The negative impacts of global change drivers (i.e. N and P addition, warming) on community temporal stability increased with the degree of species loss but decreased with increasing stability of grasses. Moreover, the negative impacts of nutrient addition and precipitation decrease on community stability was lessened while the positive effect of precipitation increase on community stability was enhanced in grasslands with higher historical precipitation variability, greater soil fertility and longer experimental duration. 5. Synthesis. Our findings demonstrate that N-based nutrient additions and drought destabilise grassland productivity, while precipitation increase enhances community stability. Impacts of global changes on community productivity and stability are mediated by species richness, plant functional group, site-specific | 2851

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“…4). Consistent with previous analyses, we found that nutrient addition may decrease invariability through decreasing species richness (Hautier et al ., 2015; Carroll et al ., 2021), but this indirect negative effect, together with the negative effects through resilience were offset by the positive effects through resistance. Combined, nutrient addition did not impact invariability.…”

Section: Discussionmentioning

confidence: 99%

“…In grasslands, nutrient addition has been shown to decrease resistance in aboveground primary productivity during dry climate extremes as well as temporal invariability, while its effects on resilience after dry climate extremes are mixed (Tilman & Downing, 1994; Xu et al ., 2014; Hautier et al ., 2015; Bharath et al ., 2020; Meng et al ., 2021; Van Sundert et al ., 2021; Carroll et al ., 2021). However, to date, few empirical studies have investigated the impact of nutrient addition on resistance during and resilience after wet climate extremes, which are becoming increasingly frequent just as dry climate extremes globally (IPCC, 2019).…”

Section: Introductionmentioning

confidence: 99%

Change in functional trait diversity mediates the effects of nutrient addition on grassland stability

Chen¹,

Wang

Seabloom

et al. 2022

Preprint

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Eutrophication impacts plant diversity such as species richness, functional trait diversity and composition of grassland communities globally, but whether and how these changes affect the functional stability of grasslands under increasing climate extremes is unknown. We quantify the direct and diversity-mediated effects of nutrient addition on functional stability as measured by resistance during and resilience after dry and wet growing seasons, and temporal invariability of community productivity across 19 grasslands spanning four continents. We found that nutrient addition increased resistance during dry and wet growing seasons, although the increased resistance during wet growing seasons was partly offset by the indirect negative effects of nutrient addition promoting fast-growing communities and reducing slow-fast functional diversity. Nutrient addition had, however, weak net effects on resilience and invariability.

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Nutrient identity modifies the destabilising effects of eutrophication in grasslands

Cited by 22 publications

References 79 publications

Impacts of nutrient addition on soil carbon and nitrogen stoichiometry and stability in globally-distributed grasslands

Impacts of nutrient addition on soil carbon and nitrogen stoichiometry and stability in globally-distributed grasslands

Multiple global changes drive grassland productivity and stability: A meta‐analysis

Change in functional trait diversity mediates the effects of nutrient addition on grassland stability

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