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Wood, Rachel A; Poulton, Simon W; Prave, Anthony R; Hoffmann, Karl-Heinz; Clarkson, Matthew O; Guilbaud, R; Lyne, J W; Tostevin, Rosalie; Bowyer, Pete; Penny, A M; Curtis, Alexandra; Kasemann, Simone A (2015): Geochemical analysis of nine sections from the Nama Group, Namibia [dataset publication series]. PANGAEA, https://doi.org/10.1594/PANGAEA.847494, Supplement to: Wood, RA et al. (2015): Dynamic redox conditions control late Ediacaran metazoan ecosystems in the Nama Group, Namibia. Precambrian Research, 261, 252-271, https://doi.org/10.1016/j.precamres.2015.02.004

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Abstract:
The first appearance of skeletal metazoans in the late Ediacaran (~550 million years ago; Ma) has been linked to the widespread development of oxygenated oceanic conditions, but a precise spatial and temporal reconstruction of their evolution has not been resolved. Here we consider the evolution of ocean chemistry from ~550 to ~541 Ma across shelf-to-basin transects in the Zaris and Witputs Sub-Basins of the Nama Group, Namibia. New carbon isotope data capture the final stages of the Shuram/Wonoka deep negative C-isotope excursion, and these are complemented with a reconstruction of water column redox dynamics utilising Fe-S-C systematics and the distribution of skeletal and soft-bodied metazoans. Combined, these inter-basinal datasets provide insight into the potential role of ocean redox chemistry during this pivotal interval of major biological innovation.
The strongly negative d13C values in the lower parts of the sections reflect both a secular, global change in the C-isotopic composition of Ediacaran seawater, as well as the influence of 'local' basinal effects as shown by the most negative d13C values occurring in the transition from distal to proximal ramp settings. Critical, though, is that the transition to positive d13C values postdates the appearance of calcified metazoans, indicating that the onset of biomineralization did not occur under post-excursion conditions.
Significantly, we find that anoxic and ferruginous deeper water column conditions were prevalent during and after the transition to positive d13C that marks the end of the Shuram/Wonoka excursion. Thus, if the C isotope trend reflects the transition to global-scale oxygenation in the aftermath of the oxidation of a large-scale, isotopically light organic carbon pool, it was not sufficient to fully oxygenate the deep ocean.
Both sub-basins reveal highly dynamic redox structures, where shallow, inner ramp settings experienced transient oxygenation. Anoxic conditions were caused either by episodic upwelling of deeper anoxic waters or higher rates of productivity. These settings supported short-lived and monospecific skeletal metazoan communities. By contrast, microbial (thrombolite) reefs, found in deeper inner- and mid-ramp settings, supported more biodiverse communities with complex ecologies and large skeletal metazoans. These long-lived reef communities, as well as Ediacaran soft-bodied biotas, are found particularly within transgressive systems, where oxygenation was persistent. We suggest that a mid-ramp position enabled physical ventilation mechanisms for shallow water column oxygenation to operate during flooding and transgressive sea-level rise. Our data support a prominent role for oxygen, and for stable oxygenated conditions in particular, in controlling both the distribution and ecology of Ediacaran skeletal metazoan communities.
Coverage:
Median Latitude: -25.995502 * Median Longitude: 16.344554 * South-bound Latitude: -27.474722 * West-bound Longitude: 16.000000 * North-bound Latitude: -23.860230 * East-bound Longitude: 16.692500
Size:
12 datasets

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Datasets listed in this publication series

  1. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S2) Geochemical analysis of Site 1, Zwartmodder, Zaris Basin. https://doi.org/10.1594/PANGAEA.847424
  2. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S3) Geochemical analysis of Site 3, Omkyk. https://doi.org/10.1594/PANGAEA.847425
  3. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S4) Geochemical analysis of Site 3, Zebra_River. https://doi.org/10.1594/PANGAEA.847426
  4. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S5) Geochemical analysis of Site 4, Driedoornvlagte. https://doi.org/10.1594/PANGAEA.847428
  5. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S6) Geochemical analysis of Site 5, Brak. https://doi.org/10.1594/PANGAEA.847481
  6. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S7A) Geochemical analysis of Site 6, Arasab: Carbonates. https://doi.org/10.1594/PANGAEA.847482
  7. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S7B) Geochemical analysis of Site 6, Arasab: Shales. https://doi.org/10.1594/PANGAEA.847483
  8. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S8) Geochemical analysis of Site 7, Grens. https://doi.org/10.1594/PANGAEA.847484
  9. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S9A) Geochemical analysis of Site 8, Pinnacle Reefs: carbonates. https://doi.org/10.1594/PANGAEA.847485
  10. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S9B) Geochemical analysis of Site 8, Pinnacle Reefs: shales. https://doi.org/10.1594/PANGAEA.847486
  11. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S10A) Geochemical analysis of Site 9, Swartpunt: carbonates. https://doi.org/10.1594/PANGAEA.847488
  12. Wood, RA; Poulton, SW; Prave, AR et al. (2015): (Table S10B) Geochemical analysis of Site 9 Swartpunt: Shales. https://doi.org/10.1594/PANGAEA.847489