Changes in the Composition of Soil Organic Matter after the Transformation of Natural Beech Stands into Spruce Monoculture

The composition of soil organic matter is considered to have a key influence on C sequestration and global climate change and can be associated with changes in vegetation cover in the terrestrial ecosystem. Our study aimed to evaluate the soil chemical structures and various organic components from...

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Published inSoil systems Vol. 8; no. 3; p. 74
Main Authors Thai, Saven, Pavlů, Lenka, Vokurková, Petra, Thet, Bunthorn, Vejvodová, Kateřina, Drábek, Ondřej, Tejnecký, Václav
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.09.2024
Subjects
Acidic soils
Acidification
Aliphatic compounds
Alkaline soils
Aromatic compounds
Beech
cambisols
Carbohydrates
Carbon
Carbon content
Carboxylic acids
Cation exchange
Cation exchanging
Chemical composition
Chromatography
Climate change
Dissolved organic carbon
forest soil
Forest soils
Forests
Fourier transforms
Functional groups
Global climate
infrared spectroscopy
Leaching
Lignin
Molecular weight
Monoculture
Nutrients
Organic acids
Organic compounds
Organic matter
organic matter composition
Organic soils
Oxidation
podzols
Polysaccharides
Precipitation
Soil chemistry
Soil horizons
Soil organic matter
Soil profiles
Soil properties
Soil sciences
Soil solution
Soil structure
Soils
Stand structure
Trees
Vegetation
Vegetation cover
Czech Republic
Germany
United States > US
Norway
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Summary:The composition of soil organic matter is considered to have a key influence on C sequestration and global climate change and can be associated with changes in vegetation cover in the terrestrial ecosystem. Our study aimed to evaluate the soil chemical structures and various organic components from available or reactive to more stable forms in forest soils affected by acidification and after conversion from fairly close to natural beech (Fagus sylvatica) stands to a spruce (Picea abies) monoculture. Our results revealed that the beech stands had higher contents of dissolved organic carbon and low molecular mass organic acid compared to the spruce stands. The aliphatic CH groups within the soluble alkaline-extractable organic substance (AEOS) gradually disappeared with deeper soil horizons under both forest species, while the presence of aliphatic CH groups in the low-solubility AEOS was more pronounced in the A horizon under spruce and relatively increased with depth under beech stands. The carboxylic groups were more prevalent in deeper soil horizons, while polysaccharide chains and nitrogen functional groups decreased with depth under both forest stands but were more prevalent under beech than under spruce stands. These findings suggest that the stability of organic matter through the forest soil profiles increased due to the transformation of various organic compounds from litter to more stable organic matter with higher amounts of lignin components to greater amounts of carboxylic groups and aromatic groups in deeper soil horizons. Furthermore, a higher number of mobile components of soil organic matter and carboxylic acids, together with lower pH and cation exchange capacity under spruce, resulted in the leaching of nutrients, releasing risk elements into the soil solution and accelerating the podzolization process.
ISSN:2571-8789
2571-8789
DOI:10.3390/soilsystems8030074