Home > Organic matter oxidation and sediment chemistry in mixed terrigenous-carbonate sands of Ningaloo Reef, Western Australia

Organic matter oxidation and sediment chemistry in mixed terrigenous-carbonate sands of Ningaloo Reef, Western Australia


Posted on 02 August 2011

TitleOrganic matter oxidation and sediment chemistry in mixed terrigenous-carbonate sands of Ningaloo Reef, Western Australia
Publication TypeJournal Article
Year of Publication1996
AuthorsAlongi, D, Tirendi F, Goldrick A
JournalMarine Chemistry
Volume54
Pagination203 - 219
Date Published10/1996
ISSN03044203
Keywordsgeology, other
AbstractThe oxidation of organic matter in relation to porewater and solid-phase element chemistry was examined in mixed terrigenous-carbonate sediments in sheltered and exposed lagoons of Ningaloo Reef, Western Australia. Rates of O2 consumption and CO2 release were faster in the very fine sand (41–43% CaCO3 content) of the sheltered lagoon of Mangrove Bay (means = 10.5 mmolm−2day−1 O2 and 9.4mmolm−2day−1 CO2) than in the carbonate-rich (73% CaCO3) sand of the exposed back-reef lagoon of Ningaloo Reef (means = 2.1 mmolm−2 day−1 O2 and 3.5 mmolm−2 day−1 CO2). Rates of sulfate reduction (ΣSRR) were similarly faster in the Mangrove Bay sediments (6.1–25.3 mmolm−2day−1 S), sufficient to account for all of the organic matter mineralization. In Ningaloo reef sands, ΣSRR rates (1.0 mmol m−2 day−1 S) accounted for a significant fraction (57%) of total organic carbon oxidation. In Mangrove Bay, in contrast to previous measurements of sulfate reduction in tropical sediments, most (mean = 64%) of the reduced 35S was incorporated into the acid-volatile sulflde fraction with a buildup of iron sulfides. In contrast to most carbonate-bearing sediments, the production and accumulation of Fe sulfides (most evident in Mangrove Bay) increased pH to levels promoting carbonate precipitation. Higher decomposition rates in Mangrove Bay are attributed to restricted water circulation, a richer benthic community, and geomorphology conducive to greater input and retention of mangrove- and macroalgae-derived detritus. At both sites, the lack of a clear zonational sequence of porewater solutes, discrepancies between depth profiles of solutes and solid-phase elements, and high core-to-core variation in conservative element concentrations and in rates of bacterial activity, suggest non-steady state diagenesis. Non-steady state conditions may be fostered by a combination of factors, such as physical disturbances, temporal changes in rates and quality of organic sedimentation, and tidal advection.
URLhttp://www.sciencedirect.com/science/article/pii/0304420396000370
DOI10.1016/0304-4203(96)00037-0
Short TitleMarine Chemistry
Refereed DesignationRefereed