Effect of settled diatom-aggregates on benthic nitrogen cycling

The marine sediment hosts a mosaic of microhabitats. Recently it has been demonstrated that the settlement of phycodetrital aggregates can induce local changes in the benthic O-2 distribution due to confined enrichment of organic material and alteration of the diffusional transport. Here, we show ho...

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Bibliographic Details
Published in:Limnology and Oceanography
Main Authors: Marzocchi, Ugo, Thamdrup, Bo, Stief, Peter, Glud, Ronnie N.
Format: Article in Journal/Newspaper
Language:English
Published: 2018
Subjects:
OXYGEN MINIMUM ZONE
MARINE-SEDIMENTS
SEASONAL-VARIATION
ANOXIC CONDITIONS
CARBON TURNOVER
FRESH-WATER
SAGAMI BAY
SEA-ICE
DENITRIFICATION
NITRATE
Sea ice
Online Access:https://pure.au.dk/portal/da/publications/effect-of-settled-diatomaggregates-on-benthic-nitrogen-cycling(9280c641-68e3-44c9-b28f-ca9a5660664d).html
https://doi.org/10.1002/lno.10641
https://pure.au.dk/ws/files/165615712/Marzocchi_et_al_2018_Limnology_and_Oceanography.pdf
http://www.scopus.com/inward/record.url?scp=85040819388&partnerID=8YFLogxK
Description
Summary:The marine sediment hosts a mosaic of microhabitats. Recently it has been demonstrated that the settlement of phycodetrital aggregates can induce local changes in the benthic O-2 distribution due to confined enrichment of organic material and alteration of the diffusional transport. Here, we show how this microscale O-2 shift substantially affects benthic nitrogen cycling. In sediment incubations, the settlement of diatom-aggregates markedly enhanced benthic O-2 and NO3- consumption and stimulated NO2- and NH4+ production. Oxygen microprofiles revealed the rapid development of anoxic niches within and underneath the aggregates. During 120 h following the settling of the aggregates, denitrification of NO3- from the overlying water increased from 13.5 mu mol m(-2) h(-1) to 24.3 mu mol m(-2) h(-1), as quantified by N-15 enrichment experiment. Simultaneously, N-2 production from coupled nitrification-denitrification decreased from 33.4 mu mol m(-2) h(-1) to 25.9 mu mol m(-2) h(-1), probably due to temporary inhibition of the benthic nitrifying community. The two effects were of similar magnitude and left the total N-2 production almost unaltered. At the aggregate surface, nitrification was, conversely, very efficient in oxidizing NH4+ liberated by mineralization of the aggregates. The produced NO3- was preferentially released into the overlying water and only a minor fraction contributed to denitrification activity. Overall, our data indicate that the abrupt change in O-2 microdistribution caused by aggregates stimulates denitrification of NO3- from the overlying water, and loosens the coupling between benthic nitrification and denitrification both in time and space. The study contributes to expanding the conceptual and quantitative understanding of how nitrogen cycling is regulated in dynamic benthic environments.

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