Microbial processes controlling P availability in forest spodosols as affected by soil depth and soil properties

Because carbon dioxide (CO2) concentration is rising, increases in plant biomass and productivity of terrestrial ecosystems are expected. However, phosphorus (P) unavailability may disable any potential enhanced growth of plants in forest ecosystems. In response to P scarcity under elevated CO2, tre...

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Vydané v:Soil biology & biochemistry Ročník 44; číslo 1; s. 39 - 48
Hlavní autori: Achat, David L., Augusto, Laurent, Bakker, Mark R., Gallet-Budynek, Anne, Morel, Christian
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Amsterdam Elsevier Ltd 01.01.2012
Elsevier
Predmet:
acid phosphatase
Agricultural sciences
Agronomy. Soil science and plant productions
aluminum
Biochemistry and biology
Biological and medical sciences
biomass
carbon dioxide
Chemical, physicochemical, biochemical and biological properties
forest ecosystems
forest growth
forest soils
Forest spodosols
forests
Fundamental and applied biological sciences. Psychology
iron
Life Sciences
Microbial P
mineralization
Mineralization of P in ‘dead’ organic matter
nutrients
organic compounds
Organic matter
P availability
phosphorus
Physics, chemistry, biochemistry and biology of agricultural and forest soils
process control
soil depth
soil horizons
soil organic matter
Soil properties
Soil science
soil stabilization
Soil study
soil water
Spodosols
Surface and deep soil layers
topsoil
trees
underground mining
Mineralization of P in ‘dead’ organic matter
Surface and deep soil layers
P availability
Microbial P
Soil properties
Forest spodosols
Forests
Organic matter
Deep soil
Available nutrient
Property of soil
Phosphorus
Depth
Mineralization
Soil science
Microorganism
Spodosols
Mineralization of P in 'dead' organic matter
SURFACE AND DEEP SOIL LAYERS
FOREST SPODOSOLS
MICROBIAL P
P AVAILABILITY
SOIL PROPERTIES
PROPRIÉTÉ DU SOL
PHOSPHORE MICROBIEN
SOUS-SOL
COUCHE PROFONDE DU SOL
MINERALIZATION OF P IN ‘DEAD’ ORGANIC MATTER
ISSN:0038-0717, 1879-3428
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Shrnutí:Because carbon dioxide (CO2) concentration is rising, increases in plant biomass and productivity of terrestrial ecosystems are expected. However, phosphorus (P) unavailability may disable any potential enhanced growth of plants in forest ecosystems. In response to P scarcity under elevated CO2, trees may mine deeper the soil to take up more nutrients. In this scope, the ability of deep horizons of forest soils to supply available P to the trees has to be evaluated. The main objective of the present study was to quantify the relative contribution of topsoil horizons and deep horizons to P availability through processes governed by the activity of soil micro-organisms. Since soil properties vary with soil depth, one can therefore assume that the role of microbial processes governing P availability differs between soil layers. More specifically, our initial hypothesis was that deeper soil horizons could substantially contribute to total plant available P in forested ecosystems and that such contribution of deep horizons differs among sites (due to contrasting soil properties). To test this hypothesis, we quantified microbial P and mineralization of P in ‘dead’ soil organic matter to a depth of 120 cm in forest soils contrasting in soil organic matter, soil moisture and aluminum (Al) and iron (Fe) oxides. We also quantified microbiological activity and acid phosphomonoesterase activity. Results showed that the role of microbial processes generally decreases with increasing soil depth. However, the relative contribution of surface (litter and 0–30 cm) and deep (30–120 cm) soil layers to the stocks of available P through microbial processes (51–62 kg P ha−1) are affected by several soil properties, and the contribution of deep soil layers to these stocks vary between sites (from 29 to 59%). This shows that subsoils should be taken into account when studying the microbial processes governing P availability in forest ecosystems. For the studied soils, microbial P and mineralization of P in ‘dead’ soil organic matter particularly depended on soil organic matter content, soil moisture and, to a minor extent, Al oxides. High Al oxide contents in some sites or in deep soil layers probably result in the stabilization of soil organic compounds thus reducing microbiological activity and mineralization rates. The mineralization process in the litter also appeared to be P-limited and depended on the C:P ratio of soil organic matter. Thus, this study highlighted the effects of soil depth and soil properties on the microbial processes governing P availability in the forest spodosols. ► We quantify the stocks of available P through microbial processes. ► We assess the relative contributions of surface and deep soil layers to these stocks. ► Microbial P and mineralized organic P decrease with increasing soil depth. ► The role of the deep soil layers (30–120 cm) can however be significant. ► The contributions of the different soil layers depend on several soil properties.
Bibliografia:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0038-0717
1879-3428
DOI:10.1016/j.soilbio.2011.09.007