Nutrient cycling efficiency explains the long-term effect of ecosystem engineers on primary production - Bioemco Access content directly
Journal Articles Functional Ecology Year : 2007

Nutrient cycling efficiency explains the long-term effect of ecosystem engineers on primary production

Abstract

1. Soil organisms, such as earthworms, accelerate mineralization of soil organic matter and are thought to be beneficial for plant growth. This has been shown in short-term microcosm experiments. It is thus legitimate to ask whether these increases in plant growth are due to brief pulses of mineralization or whether these increases are long-lasting. 2. This question was addressed using a system of differential equations modelling the effects of decomposers on nutrient cycling via trophic (nutrient assimilation) and nontrophic effects (through their ecosystem engineering activities). 3. The analytical study of this model showed that these processes increase primary production in the long term when they recycle nutrients efficiently, allowing a small fraction of the recycled nutrients to be leached out of the ecosystem. 4. Mineralization by the ecosystem engineering activities of decomposers seems to deprive them of a resource. However, it was shown that a decomposer may increase its own biomass, through its ecosystem engineering activities, provided the created recycling loop is efficient enough. 5. Mechanisms through which earthworms may modify the efficiency of nutrient cycling are discussed. The necessity of measuring the effect of earthworms on the nutrient input-output balance of ecosystems under field conditions is emphasized.

Dates and versions

bioemco-00393839 , version 1 (10-06-2009)

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Sébastien Barot, Sébastien Barot, Alexis Ugolini, Fadia Bekkal Brikci. Nutrient cycling efficiency explains the long-term effect of ecosystem engineers on primary production. Functional Ecology, 2007, 21 (1), pp.1-10. ⟨10.1111/j.1365-2435.2006.01225.x⟩. ⟨bioemco-00393839⟩
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