Balance of assimilative and dissimilative nitrogen processes in a diatom-rich tidal flat sediment
Publication date
2012
Authors
Dähnke, K.
Moneta, A.
Veuger, B.
Soetaert, K.
Middelburg, J.J.
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(c) UU Universiteit Utrecht, 2012
Abstract
Tidal flat sediments are subject to repetitive mixing
and resuspension events. In a short-term (24 h) 15Nlabelling
experiment, we investigated reactive nitrogen cycling
in a tidal flat sediment following an experimentally induced
resuspension event. We focused on (a) the relative importance
of assimilatory versus dissimilatory processes and
(b) the role of benthic microalgae therein. 15N-labelled substrate
was added to homogenized sediment, and 15N was subsequently
traced into sediment and dissolved inorganic nitrogen
(DIN) pools. Integration of results in a N-cycle model
allowed us to quantify the proportion of major assimilatory
and dissimilatory processes in the sediment.
Upon sediment disturbance, rates of dissimilatory processes
like nitrification and denitrification were very high,
but declined rapidly towards a steady state. Once this was
reached, the balance between assimilation and dissimilation
in this tidal mudflat was mainly dependent on the nitrogen
source: nitrate was utilized almost exclusively dissimilatory
via denitrification, whereas ammonium was rapidly assimilated,
with about a quarter of this assimilation due to benthic
microalgae (BMA). Benthic microalgae significantly affected
the nitrogen recycling balance in sediments, because
in the absence of BMA activity the recovering sediment
turned from a net ammonium sink to a net source.
The driving mechanisms for assimilation or dissimilation
accordingly appear to be ruled to a large extent by external
physical forcing, with the entire system being capable
of rapid shifts following environmental changes. Assimilatory
pathways gain importance under stable conditions, with
a substantial contribution of BMA to total assimilation