Abstract
Effects of sediment mixing and benthic algal production on fossil pigment profiles were quantified by fine-interval analysis of cores in a transect across the basin of Paul Lake, MI. Annually resolved profiles (1957–1986) of carotenoids and chlorophyll a from varved sediments at deepwater (15 m) sites were compared to fine-interval (2.5–3.5 mm) stratigraphies from sites with increasing sediment mixing and benthic algal production (4 m>7 m>9 m). The degree of sediment mixing was also modelled using running means of pigment concentrations in varved sediments and compared to disturbed profiles. Effects of sediment mixing included reduction of peak pigment concentrations, broadening of peaks and migration of maxima deeper into deposits. Sedimentary signal strength was defined as the ratio of peak concentrations to baseline levels. Short-lived or weak signals (∼ 1.5 x baseline) were resolved only in the least disturbed deposits, while strong signals (5 x baseline) withstood sediment homogenization to depths greater than 1 cm (>5 year accumulation). Comparison of core-wide mean pigment concentrations suggested that cores recovered from within the photic zone are influenced by benthic algal production and will not represent either historical or current ecological dynamics in the water column. We conclude that: moderate levels of mixing do not destroy fossil pigment profiles; disturbed stratigraphies can remain ecologically interpretable; and fine-interval analyses are warranted in lakes with undisturbed 137Cs profiles and where sediment porosity <90%.
Published Version
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