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26 June 2017 Allostratigraphy and Biostratigraphy of the Upper Cretaceous (Coniacian-Santonian) Western Canada Foreland Basin
Neil H. Landman, A. Guy Plint, Irek Walaszczyk, Neil H. Landman, A. Guy Plint, Ireneusz Walaszczyk
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This bulletin contains three closely integrated papers that treat Upper Cretaceous (Coniacian-Santonian) strata of the Western Canada Foreland Basin (WCFB). Our research is the culmination of the collective efforts of seven scientists from eight institutions in the United States, Canada, Poland, and the United Kingdom. It presents the results of 12 seasons of geological fieldwork in the Rocky Mountain Foothills of Alberta. As in many other high-latitude studies, some sites were difficult to access and required transport by helicopter, and fieldwork could be carried out only in July and August. The outcrops were measured in detail, with particular attention to depositional cycles and bounding surfaces that indicate relative changes in sea level. Fossils of molluscs were collected at each locality and placed precisely within each section. The results of these outcrop investigations were integrated with a public database comprising thousands of wireline logs, supplemented by cores, which provided the regional control to reconstruct the stratal geometry, facies relationships, and paleogeography of the basin in three dimensions.

The principal purpose of our research is to present a detailed allostratigraphic and biostratigraphic framework for the Coniacian and basal Santonian succession in the WCFB. The studied strata, approximately 100 m thick, comprise the lower part of the Wapiabi Formation (Coniacian to lower Campanian) that extends east from the Rocky Mountain Foothills and covers much of Alberta, and parts of Saskatchewan and Manitoba. Because of rapid flexural subsidence in the western foredeep, the Wapiabi Formation preserves an expanded record of terrestrial and shallow marine sedimentation. The rocks are dominated by mudstone and subordinate sandstone and were deposited on a very low-gradient, storm-dominated marine ramp. The rocks are organized into a series of upward-coarsening, upwardshoaling successions, bounded by marine flooding surfaces. These surfaces constitute proxy time planes that provide a framework within which to assess the temporal and spatial distribution of the molluscan fossils that furnish the basis for biostratigraphic correlation. The WCFB thus represents a natural laboratory in which to elucidate the interplay between the principal physical controls on sedimentation, namely tectonism, sediment supply, and eustasy, as well as the evolutionary patterns of the organisms that lived in the area during this time.

In the first paper of the bulletin, Plint et al. synthesize information from well-exposed sections in the fold-and-thrust belt of the Rocky Mountain Foothills and combine this information with data from a large correlation grid of wireline logs, supplemented by a few cores. In the Coniacian part of the section, they identify 24 flooding surfaces that can be traced for >750 km along strike in the subsurface. These flooding surfaces form the boundaries of 24 informal allomembers. Some of these surfaces are mantled with intra- or extrabasinal pebbles that imply a phase of shallowing and, potentially, subaerial emergence of the inner part of the ramp. Flooding surfaces represent small intervals of time relative to the rock units that they bound and, therefore, allow the subsidence history of the basin to be reconstructed in a series of relatively short time-steps. This new allostratigraphic framework emphasizes the importance of marine erosional surfaces, and their genetic relationship to relative changes in sea level. Development of such a regional subsurface allostratigraphic framework helps resolve stratal geometry and facies distributions, from which paleogeography, paleobathymetry, subsidence patterns, relative sea-level changes, and overall depositional history can be reconstructed.

The allostratigraphic framework constitutes the physical and temporal matrix within which the vertical and lateral distribution of molluscan fossils, principally inoceramid bivalves and scaphitid ammonites, can be assessed. Regional mapping reveals that allomembers, which exhibit a neartabular geometry, can be grouped into “tectono-stratigraphic units” that span hundreds of thousands of years and fill saucer-shaped, flexural depocenters. Successive depocenters are offset laterally by several hundred km, which probably reflects episodic lateral shifts in the locus of active thickening in the Cordilleran orogenic wedge, and a corresponding lateral shift in the locus of maximum isostatic subsidence.

As a complement to the allostratigraphic study, Plint et al. present preliminary carbon-isotope data from one section of Coniacian strata in Alberta, and compare the results to the reference curve from the UK Chalk succession, and to results from coeval rocks in Colorado. On the basis of shape-matching and biostratigraphic tie-points, the Light Point, East Cliff, and White Fall carbon-isotope events (CIE) of the UK Chalk succession appear to be present in Alberta. The astronomically calibrated succession of CIE in the English Chalk suggests that each of the 24 mapped allomembers in Alberta has an average duration of approximately 125,000 kyr. Because allomembers can be traced for hundreds of km, an allogenic control, probably eustasy, appears to be the most likely genetic mechanism responsible for sea-level cycles.

The WCFB yields a rich and well-preserved molluscan fauna dominated by inoceramid bivalves. This is treated by Walaszczyk et al. in the second paper in this volume. In the upper lower Coniacian to basal Santonian, six successive inoceramid zones are recognized. In ascending stratigraphic order, they are the Cremnoceramus crassus crassus—deformis deformis Zone, the Inoceramus gibbosus Zone, the Volviceramus koeneni Zone, the V. involutus Zone, the Sphenoceramus subcardissoides Zone, and the Sphenoceramus ex gr. pachti Zone. The base of the middle Coniacian is marked by the lowest occurrence of the taxonomically variable Volviceramus fauna including V. koeneni (Müller, 1888), V. exogyroides (Meek and Hayden, 1862), and V. cardinalensis, sp. nov., in association with I. undabundus Meek and Hayden, 1862. The base of the upper Coniacian is marked by the lowest occurrence of the characteristically northern inoceramid species S. subcardissoides (Schlüter, 1877). The lowest occurrence of V. stotti sp. nov., described for the first time from the Canadian sections, is also close to this boundary. The base of the Santonian is marked by the lowest occurrence of S. ex gr. pachti (Arkhangelsky, 1912). Several of the zonal assemblages are known widely from the Euramerican biogeographic region, although they are mostly representative of the northern boreal area. This new inoceramidbased zonation allows correlation with other parts of the Euramerican biogeographic region.

The lowest occurrence of each inoceramid species can be interpreted in the context of the relative sea-level framework developed by Plint et al. The lowest occurrences of Cremnoceramus crassus crassus (Petrascheck, 1903), various species of Volviceramus, Sphenoceramus subcardissoides, and S. ex gr. pachti are immediately above major flooding surfaces, suggesting that the first appearances of these taxa are closely linked to episodes of relative sea-level rise. Thus, the boundaries of biozones appear to coincide with physical stratigraphic (flooding) surfaces. The generally rare species Inoceramus gibbosus Schlüter, 1877, is abundant in the upper part of the lower Coniacian. This species is usually absent in both Europe and North America due to a stratigraphic gap resulting from a eustatic lowstand. The preservation of this species in Canada is attributed to rapid subsidence of the foredeep, which outpaced the eustatic sea-level fall.

The WCFB also contains a rich record of scaphitid ammonites (scaphites), which are described by Landman et al. in the third paper in this issue. These species are widespread and restricted to higher latitudes and allow correlation with other parts of the Western Interior of North America, as well as with western Greenland. In ascending order, Landman et al. recognized four ammonite zones, the Scaphites (S.) preventricosus Zone, the base of which coincides with the base of the lower Coniacian, the S. (S.) ventricosus Zone, the base of which coincides with the base of the Inoceramus gibbosus Zone and marks the upper part of the lower Coniacian, the S. (S.) depressus Zone, the base of which coincides with the base of the upper Coniacian, and the Clioscaphites saxitonianus Zone, the base of which coincides with the base of the Santonian. The lowest occurrence of each scaphite species can be interpreted in the context of the relative sea-level framework developed by Plint et al. The lowest occurrence of S. (S.) preventricosus Cobban, 1952, is just above an erosional surface that indicates the beginning of a major transgression that commenced in the very latest Turonian. The lowest occurrence of S. (S.) ventricosus Meek and Hayden, 1862, is just below an interpreted highstand and prior to a regression in the latest early Coniacian. The lowest occurrence of S. (S.) depressus Reeside, 1927, is in an overall regressive succession, which marks the base of the upper Coniacian, and the lowest occurrence of Clioscaphites saxitonianus (McLearn, 1929) coincides with a major transgression at the base of the Santonian. All of these species exhibit some degree of stratigraphic overlap, which implies evolutionary episodes of cladogenesis rather than anagenesis, which was the mechanism previously postulated to explain the evolution of these scaphites.

The most distinctive feature in the ontogenetic development of these scaphites is the change in coiling during ontogeny. At the approach of maturity, the shell uncoils slightly, forming a shaft, which then recurves backward approaching the earlier secreted phragmocone. As a result, the aperture faces upward during the lifetime of the animal, so that the buccal apparatus can extend outward to collect small organisms in the water column. The sequence of species leading from Scaphites (S.) preventricosus to Clioscaphites saxitonianus appears to form an evolutionary lineage, suggesting a long-term trend toward recoiling of the adult shell, while still maintaining the same position of the aperture during life. This trend is accompanied by an increase in adult size (possibly caused by a delay in the timing of maturation) and degree of shell depression. This tendency toward more recoiled shell shapes and larger adult sizes occurred against a background of changing environmental conditions in the Western Interior Seaway during the Coniacian that reflected an overall relative rise in sea level and the expansion of the seaway to cover nearly all of Alberta. This transgression resulted in an expansion of offshore habitats that may have promoted the evolutionary appearance of larger scaphite species with more closely coiled shapes and more depressed whorl sections, which were better adapted to these environments.

ACKNOWLEDGMENTS

This work reflects the efforts of many graduate students at the University of Western Ontario including B. Norris, J. McKay, and S. Donaldson. For able field assistance over the years, we thank O. Al-Mufti, P. Angiel, R. Buckley, S. CoDyer, R. Cotton-Barratt, P. Elliott, B. Hart, Y. Hu, S. Morrow, M. O'Driscoll, K. Pavan, T. Plint, J. Shank, K. Vannelli, and R. Vesely. Funding for A.G. Plint's regional stratigraphic studies was provided by the Natural Sciences and Engineering Research Council of Canada over numerous grant cycles. Supplementary funding was provided by Canadian Hunter Ltd, Home Oil Ltd., Imperial Oil Ltd., Texaco Ltd., and Unocal Canada, Ltd. Well-log data were donated by Imperial Oil Ltd. and Divestco Ltd. A gamma ray spectrometer was donated to the University of Western Ontario by Pan Canadian Petroleum Ltd.

I. Walaszczyk acknowledges the financial support of the Faculty of Geology of the University of Warsaw (BST grant No. 173502). For his final studies in Denver in November 2016, he acknowledges NCN Grant UMO-2015/17/B/ST10/03228. He also thanks Marcin Ploch, Warsaw, for his assistance in preparing the cover photograph. D.R. Gröcke and I. Jarvis acknowledge funding by UK Natural Environment Research Council (NERC) grants NE/H021868/1 and NE/H020756/1, respectively.

N.H. Landman thanks B. Hussaini, M. Conway, and K. Sarg (AMNH) for curation of fossils, S. Thurston (AMNH) for photographing specimens and preparing figures, M. Slovacek (AMNH) for preparation of specimens and illustrations, M. Wilson (College of Wooster, Wooster, Ohio) for identification of bryozoans, N. Larson (Larson Paleontology Unlimited, Keystone, South Dakota) for preparation of specimens, S. Butts (Yale Peabody Museum, New Haven, Connecticut) for providing access to collections in her care, and B. Strilisky (TMP) for facilitating the transfer of specimens to the Tyrell Museum of Paleontology. This research was funded in part by NSF Grant DEB-1353510.

We thank John A. Chamberlain, Jr. (Brooklyn College, Brooklyn, New York), Matt P. Garb (Brooklyn College, Brooklyn, New York), Ben Hathway (Alberta Geological Survey), Gregori López (Universitat Autónoma de Barcelona, Spain), Marcin Machalski (Institute of Paleobiology, Warsaw, Poland), and Royal H. Mapes (North Carolina Museum of Natural History, Raleigh, North Carolina) for carefully reviewing earlier drafts of these manuscripts. Their detailed and perceptive comments have significantly improved the final text and figures. The authors also thank Mary Knight and the publications committee at the AMNH for their help in shepherding these manuscripts through the review and editing process, ultimately leading to publication.

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© American Museum of Natural History 2017
Neil H. Landman, A. Guy Plint, Irek Walaszczyk, Neil H. Landman, A. Guy Plint, and Ireneusz Walaszczyk "Allostratigraphy and Biostratigraphy of the Upper Cretaceous (Coniacian-Santonian) Western Canada Foreland Basin," Bulletin of the American Museum of Natural History 2017(414), 1-172, (26 June 2017). https://doi.org/10.1206/0003-0090-414.1.2
Published: 26 June 2017
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