Accurate 14C dating of peat samples is crucial if peat stratigraphies are to be used as historical archives. To analyse the variation in 14C age within small peat samples, the 14C age of different mire plant remains and peat fractions (n = 39) from 2 cm thick peat slices was determined using accelerator mass spectrometry. The 14C ages of mosses were assumed to be the most accurate. To verify this we also tested the possibility that uncertainties could be introduced by mosses at the mire surface reassimilating CO2 produced during the decomposition of old peat. The average 14C content of living mosses (110.5–110.9 absolute modern% (pM)) did not differ between three Sphagnum species, representing hummock-, carpet-and lawn-growing species. Their 14C contents were also identical, within experimental limits, to the current 14C content of the atmosphere. Depending on sampled depth and peat type, the differences in calibrated 14C age between different fragments or fractions, within specific 2 cm thick peat samples, varied between 365 and ~1000 years, with one exceptional deviation of 2125 years in a sample from a mesotrophic sedge peat. Alkali-treated peat samples always gave greater ages than the corresponding untreated peat samples and small-size fractions (<0.045 mm), indicating that the fraction removed by standard alkali treatment is very similar to the small-size fraction. When compared to alkali-treated moss fragments, most other fractions and fragments deviated considerably. Even alkali-treated bulk samples deviated from the alkali-treated moss fragments. We propose that Sphagnum plant fragments should be used in 14C AMS dating of peat since they yield the most reliable 14C dates.
Background and aims Plant litter chemistry is a key driver of decomposition in peatlands. This study explored the relative contributions of phylogeny and environment to litter chemistry of peat mosses (Sphagnum), the key peat-forming plants on earth. Methods Fifteen Sphagnum species, representing three taxonomic sections ACUTIFOLIA, CUSPIDATA and SPHAGNUM, were sampled across a wide range of hydro-geochemical conditions. For all species we characterised chemical composition within (i) inorganic elements, (ii) carbohydrate polymers (iii) noncarbohydrates. Results The variation in carbohydrates was mostly explained by taxonomic section, suggesting phylogenetic conservation of carbohydrate composition. ACUTIFOLIA species invested relatively more in pectins, whereas CUSPIDATA and SPHAGNUM species invested more in hemicellulose. The composition of non-carbohydrates was mainly influenced by environment, except for some constituents for which the variation was more correlated to phylogeny. Finally, the variation in inorganic element concentrations mostly reflected hydro-geochemical conditions within and between peatlands. Conclusions The separation into an environmentally independent, phylogenetically conserved group of compounds (structural carbohydrates) and an environmentally dependent, variable group of compounds (inorganic elements, non-carbohydrates) has important implications both for understanding patterns in and for upscaling of spatially variable ecosystem processes associated with peat decomposition such as carbon sequestration, nutrient cycling and greenhouse gas emissions.
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