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Early diagenesis of chloropigment biomarkers in the lower Mississippi River and Louisiana shelf: implications for carbon cycling in a river-dominated margin

Sediment core samples were collected from two sites in the lower Mississippi River, an oxic shelf site and a hypoxic shelf site (in September 1998 and July 1999), and from a cross-shelf transect (in April 2000), to examine the differential effects of redox and sedimentation rate on carbon decay dyna...

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Published in:	Marine chemistry 2005-01, Vol.93 (2), p.159-177
Main Authors:	Chen, Nianhong, Bianchi, Thomas S., McKee, Brent A.
Format:	Article
Language:	English
Subjects:	Brackish Chlorophyll- a Early diagenesis Earth sciences Earth, ocean, space Exact sciences and technology External geophysics Geochemistry Hypoxia Louisiana continental shelf Lower Mississippi River Marine Mineralogy Physical and chemical properties of sea water Physics of the oceans Pigment decay products Silicates Water geochemistry
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container_title	Marine chemistry
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creator	Chen, Nianhong Bianchi, Thomas S. McKee, Brent A.
description	Sediment core samples were collected from two sites in the lower Mississippi River, an oxic shelf site and a hypoxic shelf site (in September 1998 and July 1999), and from a cross-shelf transect (in April 2000), to examine the differential effects of redox and sedimentation rate on carbon decay dynamics in a river-dominated margin. Downcore distribution of pigments, bulk organic carbon and nitrogen, and radioactive isotopes ( 210Pb, 7Be) were used to evaluate the decomposition and preservation of pigments and bulk organic carbon. The distinctly different sedimentary regimes and dynamic nature of the LA shelf limit the application of diagenetic models. Sedimentation processes in the lower Mississippi River and oxic shelf sites were significantly impacted by the river discharge. In areas with low sedimentation, the depth of the surface mixed layer fluctuated with seasonal variation of weather forcing. It was observed that pigment decay rate constants in the mixed layer (7.52 year −1 for chlorophyll- a) were greater than those in the accumulation layer (0.14–0.22 year −1 for chlorophyll- a) by 1–2 orders of magnitude. This suggests that enhanced decomposition of reactive organic carbon occurred in the mixed layer at locations with low sedimentation rates—due to higher decay rates. Conversely, at locations with high sedimentation rates (>10 cm year −1), the reactive carbon pool was rapidly buried below the mixed layer. The surface mixed layer likely worked as a biogeochemical reactor receiving high inputs of phytodetritus, supported by an active microbial community. We propose that despite the frequency of occurrence of bottom water hypoxia on the Louisiana shelf, sedimentation rate and lability of organic matter are more important in controlling the preservation of organic carbon.
doi_str_mv	10.1016/j.marchem.2004.08.005
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Downcore distribution of pigments, bulk organic carbon and nitrogen, and radioactive isotopes ( 210Pb, 7Be) were used to evaluate the decomposition and preservation of pigments and bulk organic carbon. The distinctly different sedimentary regimes and dynamic nature of the LA shelf limit the application of diagenetic models. Sedimentation processes in the lower Mississippi River and oxic shelf sites were significantly impacted by the river discharge. In areas with low sedimentation, the depth of the surface mixed layer fluctuated with seasonal variation of weather forcing. It was observed that pigment decay rate constants in the mixed layer (7.52 year −1 for chlorophyll- a) were greater than those in the accumulation layer (0.14–0.22 year −1 for chlorophyll- a) by 1–2 orders of magnitude. This suggests that enhanced decomposition of reactive organic carbon occurred in the mixed layer at locations with low sedimentation rates—due to higher decay rates. Conversely, at locations with high sedimentation rates (>10 cm year −1), the reactive carbon pool was rapidly buried below the mixed layer. The surface mixed layer likely worked as a biogeochemical reactor receiving high inputs of phytodetritus, supported by an active microbial community. 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Downcore distribution of pigments, bulk organic carbon and nitrogen, and radioactive isotopes ( 210Pb, 7Be) were used to evaluate the decomposition and preservation of pigments and bulk organic carbon. The distinctly different sedimentary regimes and dynamic nature of the LA shelf limit the application of diagenetic models. Sedimentation processes in the lower Mississippi River and oxic shelf sites were significantly impacted by the river discharge. In areas with low sedimentation, the depth of the surface mixed layer fluctuated with seasonal variation of weather forcing. It was observed that pigment decay rate constants in the mixed layer (7.52 year −1 for chlorophyll- a) were greater than those in the accumulation layer (0.14–0.22 year −1 for chlorophyll- a) by 1–2 orders of magnitude. This suggests that enhanced decomposition of reactive organic carbon occurred in the mixed layer at locations with low sedimentation rates—due to higher decay rates. Conversely, at locations with high sedimentation rates (>10 cm year −1), the reactive carbon pool was rapidly buried below the mixed layer. The surface mixed layer likely worked as a biogeochemical reactor receiving high inputs of phytodetritus, supported by an active microbial community. 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subjects	Brackish Chlorophyll- a Early diagenesis Earth sciences Earth, ocean, space Exact sciences and technology External geophysics Geochemistry Hypoxia Louisiana continental shelf Lower Mississippi River Marine Mineralogy Physical and chemical properties of sea water Physics of the oceans Pigment decay products Silicates Water geochemistry
title	Early diagenesis of chloropigment biomarkers in the lower Mississippi River and Louisiana shelf: implications for carbon cycling in a river-dominated margin
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