Maastrichtian
Alberta, Canada
Dinosaurs:
Tyrannosauridae indet.
Albertosaurus sarcophagus
Tyrannosaurus rex
Ornithomimidae indet.
Ricardoestesia gilmorei
Ricardoestesia isosceles
Dromaeosauridae indet.
Dromaeosaurus albertensis
Saurornitholestes langstoni
Paronychodon sp.
Troodon sp.
Caenagnathidae indet.
Ornithischia indet.
Ankylosaurus magniventris
Pachycephalosaurus sp.
Ceratopsidae indet.
Leptoceratops sp.
Leptoceratops gracilis
Triceratops horridus(including Triceratops albertensis)
Triceratops prorsus
Torosaurus sp.
Iguanodontia indet.
Thescelosaurus neglectus (including Thescelosaurus edmontonensis)
Parksosaurus warreni
Hadrosauridae indet.
Edmontosaurus annectens
Other Animals:
Myledaphus bipartitus
Cyclurus fragosus
Lepisosteus sp.
Albanerpetontidae indet.
Champsosaurus sp.
Haptosphenus placodon
Stypodontosaurus melletes
Chamops segnis
Odaxosaurus piger
Colpodontosaurus cracens
Parasaniwa wyomingensis
Paraderma bogerti
Crocodylidae indet.
Borealosuchus griffithi
Testudines indet.
Paracimexomys priscus
Cimolomys trochuus
Cimolomys gracilis
Cimolodon nitidus
Ptilodontidae indet.
Mesodma thompsoni
Mesodma formosa
Mesodma hensleighi
Nortedelphys jasoni
Nortedelphys magnus
Aletridelphys florencae
Pediomys elegans
Aletridelphys hatcheri
Leptalestes krejcii
Alphadon sp.
Alphadon marshi
Alphadon wilsoni
Turgidodon rhaister
Didelphodon coyi
Didelphodon vorax
Cimolestes propalaeoryctes
Cimolestes cerberoides
Cimolestes magnus
Batodon tenuis
Schowalteria clemensi
Gypsonictops hypoconus
Gypsonictops illuminatus
Alostera saskatchewanensis
Plants:
Microcarpolithes multistriatus
Costatheca tenuis
Costatheca striata
Dictyothylakos sp.
Erlansonisporites sparassis
Balmeisporites sp.
Spermatites minimus
Azollopsis spinata
Azolla lauta
Azolla filosa
Azolla distincta
Aquilapollenites reticulatus
Aquilapollenites reductus
Aquilapollenites cf. attenuatus
Wodehouseia spinata
Notes:
The Scollard spans the uppermost dinosaur-bearing strata: a final stronghold for dinosaurs. As a Lancian faunal stage, ceratopsians were the predominant herbivore with hadrosaur populations comparatively low. Paul (2010) indicated that the primary Triceratops in the formation was T. prorsus, rather than T. horridus. The member housing the Borealosuchus is assumed to be from the Paleocene (Wu et al. 2001), however, these crocodiles have been found in indisputably Maastrichtian strata so there is no reason to believe this individual was living after the Flood. Additionally, the supposed presence of Albertosaurus in the formation may be a mistake, since albertosaurs are not known to have survived into the Maastritchtian ecological phase. If it was present, it was very rare, and the larger, more powerful Tyrannosauruswould have made life miserable for their smaller relative. Absence of coniferous trees, like sequoias or cypress, may only be a reflection of preservation happenstance or poor sampling. Either way, it seems likely that those trees, characteristic of Maastrichtian habitats, would have been present in the original environment. Certain members of the formation house fantastic arrays of microscopic pollen fossils and, some of these, especially those housing the aquatic azolla varieties, seem preserved separately from the members predominated by vertebrate fossils. Interestingly, these coaly strata tend to overlay the vertebrate fauna (Dawson et al. 1994), indicating that the plants were suspended in deepening water after the animal inhabitants of the region had already been buried. It is even possible that the azolla found the rising waters favourable for reproduction and began to release their pollen in great amounts. Indeed, the most prevalent pollen in the formation is from various forms of Salviniacea (floating ferns). Sometimes the azolla members are considered part of the Paleocene Paskapoo Formation. Because the plants and animals are so separated in the formation it is likely that a very significant portion of the ecosystem is not represented. The insect fauna may be represented by the termite poop fossils of Microcarpolithes (Gunther et Hills 1972). Although once considered an angiosperm plant seed, Microcarpolithesis probably from members of the dry-wood termite families Kalotermitidae or Mastotermitidae (Vasile et al. 2013). The original authors back in 1972 may have been referencing seeds, not insects, but given the confident assignment of other members of the genus to termite families (Colin et al. 2011), it certainly seems possible that M. multistriatusare coprolites. Costatheca has been considered a genus of mollusc (Rozanov et al. 1969 and Sepkoski 2002) or a plant (Kar et al. 2005). There are two species of Costatheca described from the formation (Gunther et Hills 1972). but these are clearly species of plant based on spore fossils. Mammals are surprisingly diverse with a variety of multituberculates, marsupials, and placentals. However, none of these got much bigger than the modern possum or badger and likely spent the majority of their lives in the treetops or undergrowth, hiding from the more dominant dinosaur species until after the end of the Cretaceous. Lizards were common and diverse.
References:
Colin, J.-P., D. Néraudeau, A. Nel, et V. Perrichot. 2011. “Termite coprolites (Insecta: Isoptera) from the Cretaceous of western France: A paleoecological insight.” Revue de micropaléontologie 54: 129-139.
Dawson, F. M., C. G. Evans, R. Marsh, R. Richardson. 1994. “Uppermost Cretaceous and Tertiary Strata of the Western Canada Sedimentary Basin.” In G. D. Mossop and I. Shetsen. Geological Atlas of the Western Canada Sedimentary Basin. Canadian Society of Petroleum Geologists and Alberta Research Council. 387-405.
Gunther, P. R., etL. V. Hills. 1972. “Megaspores and other palynomorphs of the Brazeau Formation (Upper Cretaceous), Nordegg Area, Alberta.” Geoscience and Man 4: 29-48.
Kar, R. K., A. Sahni, K. Ambwani, et D. Dutta. 2005. “Fossil flora (Costatheca and Spermatites) from the Upper Maastrichtian Deccan Intertrappean Beds of India.” Geologica Carpathica 56(2): 149-154.
Paul, G. S. 2010. The Princeton Field Guide to Dinosaurs. Princeton, NJ: Princeton University Press.
Rozanov, A. Y., V. V. Missarzhevsky, N. A. Volkova, L. G. Voronova, I. N. Krylov, B. M. Keller, I. K. Korolyuk, K. Lendzion, R. Mikhnyar, N. G. Pykhova, et A. D. Sidorov. 1969. “Tommotskiu jarus i problema nizhney granisty kembriya.” Trudy Geoligske Institut Leningrad 206: 1-379.
Sepkoski, J. J. 2002. “A compendium of fossil marine animal genera.” Bulletin of American Paleontology 363: 1-560.
Vasile, S., E. R. Boder, Z. Csiki-Sava, et Z. Szentesi. 2013. “Isopteran trace fossils from the Upper Cretaceous of Central-Eastern Europe.” In D. Tabara (ed). The Ninth Romanian Symposium on Paleontology, Iasi: Abstract Book. Iasi: University of Iasi.
Wu, X.-C., D. B. Brinkman, et R. C. Fox. 2001. “A new crocodilian (Archosauria) from the basal Paleocene of the Red Deer River Valley, southern Alberta.” Canadian Journal of Earth Science 38: 1689-1704.
No comments:
Post a Comment