Grassland productivity limited by multiple nutrients

Fay, Philip A.; Prober, Suzanne M.; Harpole, W. Stanley; Knops, Johannes M. H.; Bakker, Jonathan D.; Borer, Elizabeth T.; Lind, Eric M.; MacDougall, Andrew S.; Seabloom, Eric W.; Wragg, Peter D.; Adler, Peter B.; Blumenthal, Dana M.; Buckley, Yvonne M.; Chu, Chengjin; Cleland, Elsa E.; Collins, Scott L.; Davies, Kendi F.; Du, Guozhen; Feng, Xiaohui; Firn, Jennifer; Gruner, Daniel S.; Hagenah, Nicole; Hautier, Yann; Heckman, Robert W.; Jin, Virginia L.; Kirkman, Kevin; Klein, Julia A.; Ladwig, Laura M.; Li, Qi; McCulley, Rebecca L.; Melbourne, Brett A.; Mitchell, Charles E.; Moore, Joslin L.; Morgan, John; Risch, Anita C.; Schütz, Martin; Stevens, Carly J.; Wedin, David A.; Yang, Louie H.

doi:10.1038/nplants.2015.80

Cited by 426 publications

(465 citation statements)

References 31 publications

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“…Other low nutrient grasslands have shown a degree of NP co-limitation, with significantly greater above-ground biomass in NP treatments than in the control or with addition of N or P separately (Willems et al, 1993;Carroll et al, 2003). Across grasslands globally NP colimitation is widespread (Elser et al, 2007;Bracken et al, 2015;Fay et al, 2015). By contrast, in a Dutch study, N addition was reported to increase plant biomass in diverse chalk grassland, overriding any subtle P effects (Bobbink 1991), therefore not all calcareous grasslands are necessarily P limited.…”

Section: Impact Of N Additionmentioning

confidence: 69%

Nitrogen and phosphorus co-limitation and grazing moderate nitrogen impacts on plant growth and nutrient cycling in sand dune grassland

Ford

Roberts

Jones

2016

Science of The Total Environment

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Atmospheric nitrogen (N) deposition alters plant biodiversity and ecosystem function in grasslands worldwide. This study examines the impact of 6 years of nutrient addition and grazing management on a sand dune grassland. Results indicate that co-limitation of N and phosphorus (P) moderates the impact of realistic rates of N addition (7.5, 15 kg N ha −1 year −1 ). Combined NP addition (15 kg N + 10 kg P ha −1 year −1 ) was the only nutrient treatment to differ significantly from the control, with greater above-ground biomass (mainly moss), and enhanced N and P mineralisation rates. Grazing management altered plant functional group composition, reduced above-ground biomass and meso-faunal feeding rates, and decoupled N and P mineralisation. There were no synergistic effects of grazing and N treatment. Although NP co-limitation apparently prevents adverse impacts of N deposition above the critical load, excess N is likely to be stored in moss biomass and soil, with unknown future consequences.Capsule: This study shows that at realistic levels of N addition, NP co-limitation in a dune grassland appears to prevent adverse impacts of N on plant growth and nutrient cycling.

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Section: Impact Of N Additionmentioning

confidence: 69%

Nitrogen and phosphorus co-limitation and grazing moderate nitrogen impacts on plant growth and nutrient cycling in sand dune grassland

Ford

Roberts

Jones

2016

Science of The Total Environment

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“…The Güsewell (2004) range for co-NP limitation 307 is broader than some ranges proposed by others (e.g., Koerselman and Meuleman 1996). 308 more common than previously thought (Fay et al 2015). This suggests that past narrow N: 310 P ratio ranges may have mistakenly predicted single nutrient limitation in some 311 communities that were co-limited.…”

Section: Discussion 253mentioning

confidence: 43%

“…LAI represents the 1-sided leaf surface area available 69 for photosynthesis, and variability in this metric strongly influences key ecosystem 70 functions such as productivity and transpiration (Street et al 2012 occurs. This may also apply to LAI-TFP (total foliar phosphorus) relationships in P-limited 95 or co-NP limited systems found in many grasslands (Fay et al 2015). Furthermore, in 96 herbaceous plant communities where the canopy makes up the majority of above ground 97 biomass, such relationships may allow estimates of aboveground stocks of N and P from 98 measurements of LAI, further providing data needed for process-based modelling.…”

Section: Introduction 34mentioning

confidence: 99%

“…biomass, but additions of N and P in concert results in greater productivity than N-addition 55 alone (Fay et al 2015). Soil N and P availability vary spatially and temporally according to 56 legacies of grazing and burning, as well as edaphic properties, topography, communitythrough selective grazing preferences and patchy nutrient additions across the landscape 60 (Johnson and Matchett 2001;Raynor et al 2015).…”

Section: Introduction 34mentioning

confidence: 99%

“…In many terrestrial ecosystems, primary production is limited by nutrients (Aerts 35 and Chapin 2000; Elser et al 2007), with limitation by nitrogen (N), phosphorus (P), or co-36 limitation by both N and P common in grasslands worldwide (Fay et al 2015). Both N and P 37 play central roles in photosynthesis and cellular function (Reich et decomposition, and hence carbon and nutrient cycling), an improved understanding linking 47 canopy leaf area and N and P distributions will facilitate predictions of ecosystem 48 productivity and other ecological functions.…”

Section: Introduction 34mentioning

confidence: 99%

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Tight coupling of leaf area index to canopy nitrogen and phosphorus across heterogeneous tallgrass prairie communities

et al. 2016

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Addition of Phosphorus and Nitrogen Support the Invasiveness of Alternanthera Philoxeroides Under Water Stress

Sun

Javed

Abdolzadeh

et al. 2020

CLEAN Soil Air Water

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Coordination of plant functional traits with changes in the environment is helpful to understand the mechanisms underlying both invasiveness and adaptation of plants. Thus, to investigate the performance and functional traits in invasive Alternanthera philoxeroides (Mart.), an experiment of water stress is conducted with different nutrient concentrations. Alternanthera philoxeroides plants are grown under natural and nutrient soils and subjected to three levels of nitrogen (N) and phosphorus (P) solution: ambient P and N concentration (P−N−), P addition with an ambient N concentration (P+N−), and P addition with high N concentration (P+N+) in combination with three different irrigation water levels as 1) 100% irrigation, 2) 50% irrigation, and 3) 25% deficit irrigation. Based on results, A. philoxeroides produces significantly higher biomass in both soils under 100% irrigation with P+N− treatment and exhibits higher values of leaf area and root length. However, 25% irrigation with P−N− treatment in both soils exerts a significant negative effect on relative growth rate and root/shoot ratio of A. philoxeroides plants. Under 50% irrigation in soils with both P+N− and P+N+ treatments, high values of leaf nitrogen are recorded. Moreover, nutrient soil is more supportive to A. philoxeroides than natural soil.

show abstract

Grassland productivity limited by multiple nutrients

Cited by 426 publications

References 31 publications

Nitrogen and phosphorus co-limitation and grazing moderate nitrogen impacts on plant growth and nutrient cycling in sand dune grassland

Nitrogen and phosphorus co-limitation and grazing moderate nitrogen impacts on plant growth and nutrient cycling in sand dune grassland

Tight coupling of leaf area index to canopy nitrogen and phosphorus across heterogeneous tallgrass prairie communities

Addition of Phosphorus and Nitrogen Support the Invasiveness of Alternanthera Philoxeroides Under Water Stress

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