Integrated Ediacaran chronostratigraphy, Wernecke Mountains, northwestern Canada

Pyle, Leanne J.; Narbonne, Guy M.; James, Noël P.; Dalrymple, Robert W.; Kaufman, Alan J.

doi:10.1016/j.precamres.2004.01.004

Cited by 28 publications

(18 citation statements)

References 69 publications

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“…Remarks.-The specimen in Figure 3.8 is a discoid fossil preserved in convex hyporelief, the normal preservation for specimens of Aspidella previously described from the Blueflower Formation (Narbonne and Aitken, 1990;MacNaughton et al, 2000;Pyle et al, 2004) and elsewhere worldwide (Gehling et al, 2000;Fedonkin et al, 2007). Discoid fossils preserved as raised features on bed soles (convex hyporeliefs) are the most abundant fossils of the Ediacara biota, and formerly were described under a wide array of taxonomic names.…”

Section: Genus Aspidella Billings 1872mentioning

confidence: 75%

“…Most Ediacaran body fossils and trace fossils from the Mackenzie Mountains are from slope deposits (Dalrymple and Narbonne, 1996;MacNaughton et al, 2000;Macdonald et al, 2013;Narbonne et al, 2014;Carbone and Narbonne, 2014), although shallow-water deposits at the top of the Blueflower Formation have yielded single specimens of the probable dickinsonid Windermeria Narbonne, 1994 and an Ediacaria-morph of the holdfast disc Aspidella Billings, 1872 (Narbonne and Aitken, 1990), along with a low diversity assemblage of mainly simple, sub-horizontal burrows (Carbone and Narbonne, 2014). Shallow-water equivalents of the Blueflower Formation in the Wernecke Mountains, 250 km west-northwest of Sekwi Brook (Pyle et al, 2004), have yielded abundant Ediacara-type discoid body fossils and simple trace fossils along with a single specimen of the Ediacaran frond Charniodiscus Ford, 1958(Hofmann et al, 1983Narbonne and Hofmann, 1987;Pyle et al, 2004), and were previously cumulatively considered the only Ediacaran shallow-water assemblage from NW Canada.…”

Section: Introductionmentioning

confidence: 99%

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New Ediacaran fossils from the uppermost Blueflower Formation, northwest Canada: disentangling biostratigraphy and paleoecology

Carbone¹,

Narbonne²,

Macdonald³

et al. 2015

J. Paleontol.

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New Ediacaran fossil finds at Sekwi Brook occur in lower shoreface to offshore transition beds at the top of the Blueflower Formation, which are the most shallow-water facies and the youngest strata in which Ediacara-type fossils have been described from the Mackenzie Mountains of NW Canada. Newly discovered Ediacaran body fossils include two new tubular genera: Sekwitubulus annulatus new genus new species was a mm-diameter rigid annulated tube that was rooted to the sea bottom by a holdfast; Annulatubus flexuosus n. gen. n. sp. was a cm-diameter, flexible annulated tube. In conjunction with previously described large attachment discs representing the form-genus Aspidella and a single specimen of the dickinsonid Windermeria, these fossils define an assemblage that differs markedly from the rangeomorph-dominated deeper-water and older assemblages lower in the same section at Sekwi Brook. In contrast, trace fossils show little change upwards through the Blueflower Formation, at least in part reflecting their origin by microbial grazers on mats that formed during low-energy periods in both deep- and shallow-water environments. This implies that the stratigraphic succession of Ediacaran fossils in NW Canada and probably globally represents both evolutionary changes with age and the paleoecology of specific depositional settings.

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Section: Genus Aspidella Billings 1872mentioning

confidence: 75%

Section: Introductionmentioning

confidence: 99%

New Ediacaran fossils from the uppermost Blueflower Formation, northwest Canada: disentangling biostratigraphy and paleoecology

Carbone¹,

Narbonne²,

Macdonald³

et al. 2015

J. Paleontol.

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“…Previous investigations of the Wernecke Mountains have led to the identification of an Ediacaran mixed siliciclastic and carbonate succession that records the transition from inner shelf or platform to slope facies along a present-day north-to-south transect, specifically from the Goz/Corn Creek area (proximal or shallow water) to the Nadaleen River region (distal or deep water) (Busch et al, 2022(Busch et al, , 2023Macdonald et al, 2013;Moynihan et al, 2019;Pyle et al, 2004) (Figure 1). The Ediacaran succession stratigraphically overlies Marinoan glaciogenic strata of the Ice Brook Formation and the informal Ravensthroat cap carbonate (James et al, 2001;Macdonald et al, 2013Macdonald et al, , 2018Moynihan et al, 2019), which has been recently formalized as the Cliff Creek Formation (Busch et al, 2021).…”

Section: Geological and Paleontological Backgroundmentioning

confidence: 99%

“…dolostone. In some areas, this carbonate has been identified as the Gametrail Formation (Narbonne, 2005;Pyle et al, 2004), but recent work suggested it rests gradationally upon the Sheepbed Formation and is referred to informally as the "Sheepbed carbonate" (Busch et al, 2023;Macdonald et al, 2013). At the shallowest-water Goz A section (Figure 5), the Sheepbed carbonate is capped by a subaerial karstic unconformity and overlain by interbedded shale, sandstone, and carbonate of the Nadaleen Formation (Macdonald et al, 2013) (note the Nadaleen Formation was previously referred to as the "June Beds" by Macdonald et al (2013) before its formalization by Moynihan et al (2019)).…”

Section: Geological and Paleontological Backgroundmentioning

confidence: 99%

Deep‐water first occurrences of Ediacara biota prior to the Shuram carbon isotope excursion in the Wernecke Mountains, Yukon, Canada

Boag,

Busch,

Gooley

et al. 2024

Geobiology

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Ediacara‐type macrofossils appear as early as ~575 Ma in deep‐water facies of the Drook Formation of the Avalon Peninsula, Newfoundland, and the Nadaleen Formation of Yukon and Northwest Territories, Canada. Our ability to assess whether a deep‐water origination of the Ediacara biota is a genuine reflection of evolutionary succession, an artifact of an incomplete stratigraphic record, or a bathymetrically controlled biotope is limited by a lack of geochronological constraints and detailed shelf‐to‐slope transects of Ediacaran continental margins. The Ediacaran Rackla Group of the Wernecke Mountains, NW Canada, represents an ideal shelf‐to‐slope depositional system to understand the spatiotemporal and environmental context of Ediacara‐type organisms' stratigraphic occurrence. New sedimentological and paleontological data presented herein from the Wernecke Mountains establish a stratigraphic framework relating shelfal strata in the Goz/Corn Creek area to lower slope deposits in the Nadaleen River area. We report new discoveries of numerous Aspidella hold‐fast discs, indicative of frondose Ediacara organisms, from deep‐water slope deposits of the Nadaleen Formation stratigraphically below the Shuram carbon isotope excursion (CIE) in the Nadaleen River area. Such fossils are notably absent in coeval shallow‐water strata in the Goz/Corn Creek region despite appropriate facies for potential preservation. The presence of pre‐Shuram CIE Ediacara‐type fossils occurring only in deep‐water facies within a basin that has equivalent well‐preserved shallow‐water facies provides the first stratigraphic paleobiological support for a deep‐water origination of the Ediacara biota. In contrast, new occurrences of Ediacara‐type fossils (including juvenile fronds, Beltanelliformis, Aspidella, annulated tubes, and multiple ichnotaxa) are found above the Shuram CIE in both deep‐ and shallow‐water deposits of the Blueflower Formation. Given existing age constraints on the Shuram CIE, it appears that Ediacaran organisms may have originated in the deeper ocean and lived there for up to ~15 million years before migrating into shelfal environments in the terminal Ediacaran. This indicates unique ecophysiological constraints likely shaped the initial habitat preference and later environmental expansion of the Ediacara biota.

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“…However, these geochemical features of the basal Cambrian change 17 upwards to more evolved compositions with lower  Nd (t) values (-4.9 to -5.8 Worldwide, the Ediacaran-Cambrian boundary corresponds to a major unconformity in 27 most sections, suggesting a possible eustatic fall in sea level (Bartley et al 1998; Saylor 28 2003;Knoll et al 2004;Pyle et al 2004 Thomas et al 2004;Soulaimani et al 2004; 42 Álvaro et al 2010). 43…”

mentioning

confidence: 99%

The Ediacaran–Cambrian transition in the Cantabrian Zone (northern Spain): sub-Cambrian weathering, K-metasomatism and provenance of detrital series

Ugidos

Barba

Valladares

et al. 2016

JGS

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Ugidos, J.M., Barba, P., Valladares, M.I., Suarez, M., and Ellam, R.M. (2016) The Ediacaran-Cambrian transition in the Cantabrian Zone 1 (North Spain): sub-Cambrian weathering, K-metasomatism and provenance of detrital series. Journal of the Geological Society, 173(4), pp. 603-615. (doi:10.1144/jgs2016-004) This is the author's final accepted version.There may be differences between this version and the published version. You are advised to consult the publisher's version if you wish to cite from it.http://eprints.gla.ac.uk/115950/ Abstract: The Upper Ediacaran detrital succession in the Cantabrian Zone shows 9 geochemical and mineralogical changes resulting from sub-Cambrian weathering during 10 the Late Ediacaran worldwide sea-level fall. Relative to the unaltered rocks the altered 11 ones show crosscutting rubefaction of varying thickness a remarkable increase in illite, 12 K 2 O, Rb and Cs indicating K-metasomatism, and also depletion in MgO, CaO, Na 2 O, 13Be and Sr, but not in Zr, Nb, Y, Sc. The basal Cambrian siliciclastic rocks mostly 14 consist of detritus derived from the Ediacaran materials, as demonstrated by the 15 geochemical and Nd-isotope data [ Nd (t) ranges: -3.4 to -2.1, and -3.6 to -1.8, 16respectively)]. However, these geochemical features of the basal Cambrian change 17 upwards to more evolved compositions with lower  Nd (t) values (-4.9 to -5.8 Worldwide, the Ediacaran-Cambrian boundary corresponds to a major unconformity in 27 most sections, suggesting a possible eustatic fall in sea level (Bartley et al. 1998; Saylor 28 2003;Knoll et al. 2004;Pyle et al. 2004 Thomas et al. 2004;Soulaimani et al. 2004; 42 Álvaro et al. 2010). 43In the Cantabrian Zone (Fig. 1) which is an angular unconformity. In the Central Iberian Zone (Fig. 1A) in slope and base-of-slope environments (Valladares et al. 2000). 97The Herrería group (Fig. 2) predominantly consists of sandstones with some levels of 98 conglomerates, shales and carbonates, with a thickness varying between 900 m in 99Barrios de Luna (Fig. 1B) and 1500 m in the Cangas de Narcea-Mieldes areas (Comte 100 1959). The lower part of this group consists of conglomerates that locally displays 101 volcanic clasts, and have a lenticular geometry (Fig. 1B) followed by Rusophycus and Cruziana species, indicating that this member yielded 106 associations of ichnofossils suggestive of a Late Corduban age (Liñan et al. 2002). 107The Lower Cambrian begins with conglomerate and sandstone-shale alternations 108 deposited in alluvial and braided-channel environments at the base, which evolved 109 upwards to tidal environments. In a restricted area close to Mieldes (Fig. 1B) other Ediacaran outcrops are observable. In the IR and Sierra de la Demanda (Fig. 1A, 126 SD), the basal Lower Cambrian also has conglomerate beds but no volcanic clasts have 127 5 been reported; instead, subrounded clasts of white quartz prevail (Álvaro et al. 2008; 128 Ábalos et al. 2011). 129 Mineralogy 130XRD semi-quantitative data on the rock-forming minerals in the ru...

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Integrated Ediacaran chronostratigraphy, Wernecke Mountains, northwestern Canada

Cited by 28 publications

References 69 publications

New Ediacaran fossils from the uppermost Blueflower Formation, northwest Canada: disentangling biostratigraphy and paleoecology

New Ediacaran fossils from the uppermost Blueflower Formation, northwest Canada: disentangling biostratigraphy and paleoecology

Deep‐water first occurrences of Ediacara biota prior to the Shuram carbon isotope excursion in the Wernecke Mountains, Yukon, Canada

The Ediacaran–Cambrian transition in the Cantabrian Zone (northern Spain): sub-Cambrian weathering, K-metasomatism and provenance of detrital series

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