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Abstract
New high-resolution geochemical and sedimentological data from
Fiskegrav, East Greenland, reveal fluctuations in marine redox
conditions associated with the final disappearance of bioturbating
organisms during the latest Permian mass extinction (LPME).
Sedimentological observations imply a transgressive episode, and
associated geochemical evidence for decreasing oxygen availability and
the establishment of persistently ferruginous (Fe2 +-rich)
conditions implies the shoreward migration of oxygen deficient waters.
The long-term decline in dissolved oxygen (DO) availability could have
been exacerbated by increasing water temperatures, reducing the
solubility of oxygen and promoting thermal stratification. Mixing of the
water column could have been further inhibited by freshwater influxes
that could have generated salinity contrasts that reinforced thermal
stratification. Enhanced runoff could also have increased the delivery
of nutrients to the marine shelf, stimulating biological oxygen demand
(BOD). During the transition to persistently ferruginous conditions we
identify intervals of intermittent benthic meiofaunal recolonization,
events that we attribute to small transient increases in DO
availability. The mechanism controlling these fluctuations remains
speculative, but given the possible centennial- to millennial-scale
frequency of these changes, we hypothesise that the mid-latitude setting
of Fiskegrav during the Late Permian was sensitive to changes in
atmospheric circulation patterns, which may have influenced local
precipitation and intermittently modulated some of the processes
promoting anoxia.
Original language | English |
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Pages (from-to) | 210-223 |
Journal | Palaeogeography, Palaeoclimatology, Palaeoecology |
Volume | 485 |
Early online date | 17 Jun 2017 |
DOIs | |
Publication status | Published - 1 Nov 2017 |
Keywords
- Ferruginous sea
- Fe speciation
- East Greenland
- Stable isotopes
- Palaeoenvironment
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Dive into the research topics of 'High-frequency fluctuations in redox conditions during the latest Permian mass extinction'. Together they form a unique fingerprint.Projects
- 3 Finished
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Did biogeochemical methane cycling: Did biogeochemical methane cycling regulate the Neoarchean atmosphere?
Claire, M. (PI)
1/10/13 → 30/03/17
Project: Standard
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Response of the Nitrogen Cycle: Response of the Nitrogen Cycle to Ocean Redox Chemistry During the Great Oxidation Event
Zerkle, A. L. (PI)
16/05/13 → 15/01/14
Project: Fellowship
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Did biogeochemical methane cycling: Did biogeochemical methane cycling regulate the Neoarchean atmosphere?
Zerkle, A. L. (PI), Claire, M. (Researcher) & Izon, G. (Researcher)
16/05/13 → 14/07/16
Project: Standard