Geochemical and tectonic uplift controls on rock nitrogen inputs across terrestrial ecosystems

Morford, Scott L.; Houlton, Benjamin Z.; Dahlgren, Randy A.

doi:10.1002/2015gb005283

Cited by 26 publications

(31 citation statements)

References 84 publications

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“…Indeed, because sedimentary materials contain more N than magmatic rocks (Morford et al. ), it was expected that N remobilization might be lower in sedimentary contexts than in magmatic contexts. Our results, however, did not follow this pattern, suggesting that the direct supply of N from bedrock to plant (Morford et al.…”

Section: Discussionmentioning

confidence: 99%

Nutrient remobilization in tree foliage as affected by soil nutrients and leaf life span

Achat

Pousse²,

Nicolas³

et al. 2018

Ecological Monographs

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Nutrient remobilization is a key process in nutrient conservation in plants and in nutrient cycling in ecosystems. To predict the productivity of terrestrial ecosystems, we thus need to improve our understanding of the factors that control remobilization. We studied the remobilization rates of several major nutrients (N, P, S, K, Ca, and Mg) in 102 forest ecosystems representing large environmental gradients at the country scale (France). Total amounts or availability of nutrients in soils were correlated with nutrient remobilization: the larger the soil nutrient pool, the lower the remobilization rate (e.g., P remobilization decreased with increasing total or extractable inorganic P in soils). Soil type and soil parent material influenced nutrient remobilization indirectly through their effect on soil nutrients. Nutrient remobilization was also affected by the quality of soil organic matter (C:N and C:P ratios) and K‐Ca‐Mg antagonisms. In addition to soil properties, plant‐related parameters (nutrient concentrations in foliage and leaf life span) and climate variables (e.g., precipitation and actual evapotranspiration) were also correlated with nutrient remobilization. Using multivariate analysis, we found that soil nutrient richness and the life span of the leaf were generally the two most important factors controlling nutrient remobilization. As a whole, the nutrient remobilization rate is regulated by soil nutrients through negative feedback. This general ecological pattern is modulated by ecophysiological constraints of plants, mainly leaf life span or the capability of plants to move Ca through the phloem sap.

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Section: Discussionmentioning

confidence: 99%

Nutrient remobilization in tree foliage as affected by soil nutrients and leaf life span

Achat

Pousse²,

Nicolas³

et al. 2018

Ecological Monographs

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“…nitrogen, phosphorous, and carbon) that influence primary productivity and biomass (Cook & McElhinny, 1979;Vitousek, 2004;Elser et al, 2007;LeBauer & Treseder, 2008;Vitousek et al, 2013). This initial distribution is modified by environmental and physical factors ('passive subsidies'; Earl & Zollner, 2014), including wind, current, gravity and erosion (Zhao & Running, 2010;Cleveland et al, 2013;Houlton & Morford, 2015;Morford, Houlton & Dahlgren, 2016). In addition to these abiotic processes, biotic vectors further redistribute nutrients through various mechanisms, mostly via animal movement (Fig.…”

Section: Introduction: Animals As Important Vectors Of Nutrient Trmentioning

confidence: 99%

Vectors with autonomy: what distinguishes animal‐mediated nutrient transport from abiotic vectors?

McInturf

Pollack²,

Yang

et al. 2019

Biological Reviews

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Animal movements are important drivers of nutrient redistribution that can affect primary productivity and biodiversity across various spatial scales. Recent work indicates that incorporating these movements into ecosystem models can enhance our ability to predict the spatio‐temporal distribution of nutrients. However, the role of animal behaviour in animal‐mediated nutrient transport (i.e. active subsidies) remains under‐explored. Here we review the current literature on active subsidies to show how the behaviour of active subsidy agents makes them both ecologically important and qualitatively distinct from abiotic processes (i.e. passive subsidies). We first propose that animal movement patterns can create similar ecological effects (i.e. press and pulse disturbances) in recipient ecosystems, which can be equal in magnitude to or greater than those of passive subsidies. We then highlight three key behavioural features distinguishing active subsidies. First, organisms can transport nutrients counter‐directionally to abiotic forces and potential energy gradients (e.g. upstream). Second, unlike passive subsidies, organisms respond to the patterns of nutrients that they generate. Third, animal agents interact with each other. The latter two features can form positive‐ or negative‐feedback loops, creating patterns in space or time that can reinforce nutrient hotspots in places of mass aggregations and/or create lasting impacts within ecosystems. Because human‐driven changes can affect both the space‐use of active subsidy species and their composition at both population (i.e. individual variation) and community levels (i.e. species interactions), predicting patterns in nutrient flows under future modified environmental conditions depends on understanding the behavioural mechanisms that underlie active subsidies and variation among agents' contributions. We conclude by advocating for the integration of animal behaviour, animal movement data, and individual variation into future conservation efforts in order to provide more accurate and realistic assessments of changing ecosystem function.

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“…2; Appendix S1: Fig. This is likely a product of variations in climate, denudation, and underlying bedrock within each region, all of which affect the mobilization of N from bedrock into soil (Morford et al 2016). Similarly, across the paired lithology sites, we find that P concentrations in soil and litter are significantly influenced by the interaction between region and bedrock N content, in addition to bedrock N alone (Table 2), with the highest soil P concentrations at the two wettest sampling regions.…”

Section: Discussionmentioning

confidence: 99%

“…Similarly, across the paired lithology sites, we find that P concentrations in soil and litter are significantly influenced by the interaction between region and bedrock N content, in addition to bedrock N alone (Table 2), with the highest soil P concentrations at the two wettest sampling regions. This is likely a product of variations in climate, denudation, and underlying bedrock within each region, all of which affect the mobilization of N from bedrock into soil (Morford et al 2016).…”

Section: Discussionmentioning

confidence: 99%

Bedrock Nitrogen Weathering Stimulates Biological Nitrogen Fixation

Dynarski¹,

Morford²,

Mitchell³

et al. 2019

Bulletin Ecologic Soc America

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Global ecosystem models suggest that bedrock nitrogen (N) weathering contributes 10-20% of total N inputs to the natural terrestrial biosphere and >38% of ecosystem N supplies in temperate forests specifically. Yet, the role of rock N weathering in shaping ecological processes and biogeochemical fluxes is largely unknown. Here, we show that temperate forest ecosystems underlain by N-rich bedrock exhibit higher free-living N fixation rates than similar forests residing on N-poor parent materials, across sites experiencing a range of climate and tectonic regimes. This seemingly counterintuitive result can be explained by increased accumulation of soil C and P in high bedrock N sites, resulting in increased energy inputs and nutrient supplies to N fixing microorganisms. Our findings advance a novel ecosystem biogeochemical framework that recognizes long-term plant-soil-microbe feedbacks in shaping biogeochemical processes, with potentially widespread implications given the global distribution of bedrock N across Earth's terrestrial biomes.

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Geochemical and tectonic uplift controls on rock nitrogen inputs across terrestrial ecosystems

Cited by 26 publications

References 84 publications

Nutrient remobilization in tree foliage as affected by soil nutrients and leaf life span

Nutrient remobilization in tree foliage as affected by soil nutrients and leaf life span

Vectors with autonomy: what distinguishes animal‐mediated nutrient transport from abiotic vectors?

Bedrock Nitrogen Weathering Stimulates Biological Nitrogen Fixation

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