Liming of acidified forests changes leaf litter traits but does not improve leaf litter decomposability in forest streams

Liming of acidified forests changes leaf litter traits but does not improve leaf litter decomposability in forest streams

•Liming is often proposed to promote recovery of acidified ecosystems.•We evaluated how liming changes leaf litter traits and decomposability.•Liming significantly increased leaf litter Ca and Mg contents and reduced K content.•Leaf litter decomposition measured in a reference stream was not improve...

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Bibliographic Details
Published in:Forest ecology and management 2020-11, Vol.475, p.118431, Article 118431
Main Authors: Allen, J., Maunoury-Danger, F., Felten, V., Danger, M., Legout, A., Guérold, F.
Format: Article
Language:eng
Subjects:
Calco-magnesian liming
Ecology, environment
Headwater forest streams
Leaf litter traits
Life Sciences
Litter decomposition
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Summary:•Liming is often proposed to promote recovery of acidified ecosystems.•We evaluated how liming changes leaf litter traits and decomposability.•Liming significantly increased leaf litter Ca and Mg contents and reduced K content.•Leaf litter decomposition measured in a reference stream was not improved.•Ca-Mg liming might be insufficient for total recovery of acidified ecosystems. Liming, the spreading of Ca/MgCO3 on terrestrial ecosystems, is often used as a way to promote the recovery of terrestrial and aquatic ecosystems affected by anthropogenic acidification. When liming is applied to a watershed, surface waters may be improved directly through water chemistry changes but also indirectly through possible changes in the quality of terrestrial organic matter inputs to the stream. The aim of this study was to evaluate the effect of liming on leaf litter chemical and structural traits and their consequences on another trait, leaf litter decomposability, giving the potential for a leaf litter to be decomposed. Beech (Fagus sylvatica, L.) leaf litter was collected in forested sites on acid bedrock (granite and sandstone), limed (9 or 21 years ago) or not (controls), as well as on two calcareous reference sites. Several leaf litter traits were determined for each collection site: carbon (C), nitrogen (N), phosphorous (P), calcium (Ca), magnesium (Mg), potassium (K), lignin and cellulose content, and leaf mass area and toughness. To compare leaf litter decomposability in aquatic ecosystem, leaf litters from all sites were placed in a reference forested headwater stream over a 128-day period, in fine and coarse mesh litter bags, and leaf mass loss dynamic as well as fungal biomass were evaluated. Liming significantly increased leaf litter Ca and Mg contents and decreased K content while other measured traits remained unchanged. Leaf litters collected in limed sites exhibited significantly lower decomposition rates in coarse mesh bags but similar decomposition rates in fine mesh bags. Liming had no significant effect on fungal biomass. In contrast, leaf litter collected on the calcareous, reference sites, showed significantly different trait profiles (e.g. higher Ca, Mg, K and P contents), leading to up to twice higher decomposition rates and fungal development. Our study shows that under our experimental conditions, increases in Ca and Mg leaf litter contents arising from acidic forests liming did not improve leaf litter microbial decomposition and even tended t
ISSN:0378-1127
1872-7042