Chemistry of biogenic sediments from the equatorial Pacific

To increase our understanding of the mechanisms that control the distribution of Al and Ti within marine sediment, we performed sequential extractions targeting the chemical signatures of the loosely bound, exchangeable, carbonate, oxide, organic, opal, and residual fraction of sediment from a carbo...

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Bibliographic Details
Main Authors: Kryc, Kelly A, Murray, Richard W, Murray, David W
Format: Dataset
Language:English
Published: PANGAEA 2003
Subjects:
11031300 Multicorer1
11080952 Multicorer4
11091335 Multicorer5
11101338 Pistoncore5
11120107 Multicorer8
11161400 Multicorer11
11172115 Multicorer12
11181007 Multicorer13
11191756 Piston core 8
TT013-PC72
11230530 Multicorer18
11240508 Multicorer19
11270742 Multicorer22
11290827 Multicorer25
11291231 Pistoncore13
12062238 Multicorer37
178-1098B
Drake Passage
DRILL
Drilling/drill rig
Equatorial Pacific
GC
Gravity corer
JGOFS
Joides Resolution
Joint Global Ocean Flux Study
Leg178
MUC
MultiCorer
Ocean Drilling Program
ODP
PC
Piston corer
Thomas G. Thompson
TT013
TT013_104
TT013_113
TT013_114
TT013_148
TT013_23
TT013_27
TT013_32
TT013_4
TT013_41
TT013_58
TT013_63
TT013_66
TT013_72
TT013_88
TT013_93
Antarctic
Antarctic Peninsula
Pacific
Antarc*
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.725451
https://doi.org/10.1594/PANGAEA.725451
Description
Summary:To increase our understanding of the mechanisms that control the distribution of Al and Ti within marine sediment, we performed sequential extractions targeting the chemical signatures of the loosely bound, exchangeable, carbonate, oxide, organic, opal, and residual fraction of sediment from a carbonate-dominated regime (equatorial Pacific) and from a mixed opal-terrigenous regime (West Antarctic Peninsula). We observe a systematic partitioning of Al and Ti between sediment phases that is related to bulk Al/Ti. We show that, where we can quantify an Al(excess) component, the dissolved Al is preferentially affiliated with the oxide fraction, resulting in Al/Ti molar ratios of 500-3000. This is interpreted as the result of surface complexation in the water column of dissolved Al onto oxyhydroxides. We also observe a previously undetected Ti(excess) with as much as 80% of the total Ti in the organic fraction, which is most likely a function of metal-organic colloidal removal from the water column. In samples where the excess metals are obscured by the detrital load, the Al and Ti are almost exclusively found in the residual phase. This argues for the paired removal of Al (preferentially by the oxide component) and Ti (preferentially by the organic component) from the water column by settling particulate matter. This research builds upon earlier work that shows changes in the bulk ratio of Al to Ti in carbonate sediment from the central-equatorial Pacific that coincide with changes in the sedimentary bulk accumulation rate (BAR). The ratios that are observed are as much as three times higher than typical shale values, and were interpreted as the result of scavenging of dissolved Al onto particles settling in the water column. Because this non-terrigenous Al(excess) accounts for up to 50% of the total sedimentary Al inventory and correlates best with BAR, the bulk Al/Ti may be a sensitive tracer of particle flux and, therefore, export production. Because we show that the excess metals are the result of scavenging ...

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