Enrichment scale determines herbivore control of primary producers

Anthropogenic nutrient enrichment stimulates primary production and threatens natural communities worldwide. Herbivores may counteract deleterious effects of enrichment by increasing their consumption of primary producers. However, field tests of herbivore control are often done by adding nutrients...

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Veröffentlicht in:	Oecologia 2016-03, Vol.180 (3), p.833-840
Hauptverfasser:	Gil, Michael A, Jiao, Jing, Osenberg, Craig W
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Sprache:	eng
Schlagworte:	Analysis Animals Anthropogenic factors Biomass Biomedical and Life Sciences Ecology Ecosystem ECOSYSTEM ECOLOGY – ORIGINAL RESEARCH Ecosystems Eutrophication field experimentation Field tests Food Chain foraging Herbivores Herbivory Hydrology/Water Resources Life Sciences mathematical models Models, Biological Nutrients Plant Sciences Plants Primary production primary productivity
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creator	Gil, Michael A Jiao, Jing Osenberg, Craig W
description	Anthropogenic nutrient enrichment stimulates primary production and threatens natural communities worldwide. Herbivores may counteract deleterious effects of enrichment by increasing their consumption of primary producers. However, field tests of herbivore control are often done by adding nutrients at small (e.g., sub-meter) scales, while enrichment in real systems often occurs at much larger scales (e.g., kilometers). Therefore, experimental results may be driven by processes that are not relevant at larger scales. Using a mathematical model, we show that herbivores can control primary producer biomass in experiments by concentrating their foraging in small enriched plots; however, at larger, realistic scales, the same mechanism may not lead to herbivore control of primary producers. Instead, other demographic mechanisms are required, but these are not examined in most field studies (and may not operate in many systems). This mismatch between experiments and natural processes suggests that many ecosystems may be less resilient to degradation via enrichment than previously believed.
doi_str_mv	10.1007/s00442-015-3505-1
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Herbivores may counteract deleterious effects of enrichment by increasing their consumption of primary producers. However, field tests of herbivore control are often done by adding nutrients at small (e.g., sub-meter) scales, while enrichment in real systems often occurs at much larger scales (e.g., kilometers). Therefore, experimental results may be driven by processes that are not relevant at larger scales. Using a mathematical model, we show that herbivores can control primary producer biomass in experiments by concentrating their foraging in small enriched plots; however, at larger, realistic scales, the same mechanism may not lead to herbivore control of primary producers. Instead, other demographic mechanisms are required, but these are not examined in most field studies (and may not operate in many systems). This mismatch between experiments and natural processes suggests that many ecosystems may be less resilient to degradation via enrichment than previously believed.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer Berlin Heidelberg</pub><pmid>26572636</pmid><doi>10.1007/s00442-015-3505-1</doi><tpages>8</tpages></addata></record>
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subjects	Analysis Animals Anthropogenic factors Biomass Biomedical and Life Sciences Ecology Ecosystem ECOSYSTEM ECOLOGY – ORIGINAL RESEARCH Ecosystems Eutrophication field experimentation Field tests Food Chain foraging Herbivores Herbivory Hydrology/Water Resources Life Sciences mathematical models Models, Biological Nutrients Plant Sciences Plants Primary production primary productivity
title	Enrichment scale determines herbivore control of primary producers
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