EGU2020-832
https://doi.org/10.5194/egusphere-egu2020-832
EGU General Assembly 2020
© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.

Morphology in time and space: how does shape change with sequence stratigraphic architecture?

Judith Sclafani1, Max Christie2, Marjean Cone2, Brooke Roselle3, Audrey Bourne3, Caroline Gazze3, and Monika O'Brien2
Judith Sclafani et al.
  • 1Geology Department, Pomona College, Claremont, California, United States of America (judi.sclafani@pomona.edu)
  • 2Department of Geology, University of Illinois Urbana-Champaign, Urbana-Champaign, Illinois, United States of America
  • 3Department of Geosciences, Pennsylvania State University, University Park, Pennsylvania, United States of America

In their seminal work on stratigraphic paleobiology, Patzkowsky and Holland highlighted the need for more morphological data that are placed within a stratigraphic context in order to more robustly study the impact of environmental change on morphological disparity. The ability to collect morphological data within sequence stratigraphic architecture has been limited by technique. As a result, most morphological data are collected from museum specimens, usually without sequence stratigraphic information. We used the photogrammetry technique, Structure-from-Motion, to collect brachiopod morphological data from outcrops in the Late Ordovician Cincinnati Arch (Indiana, Ohio, Kentucky; USA) and quantify morphological change within an established sequence stratigraphic architecture.

SfM uses 2D photographs taken from different angles to reconstruct a 3D shape. We photographed external valves of brachiopods in the field in 360 degrees (approximately 24 photos per specimen) and used the SfM software ‘Agisoft Metashape’ to make 3D models of those specimens. We exported these models into R and used the package ‘geomorph’ to generate a set of semi-landmarks. We used these to create a morphospace to explore the effects of environment and time on 3D shape.

Results indicate that brachiopod shells separate in morphospace according to their degree of inflation and roundness. These differences are likely controlled by environmental conditions at each position along a water depth gradient. Additionally, our results are consistent with the previously observed breakdown of the environmental gradient in response to the Richmondian invasion. In particular, for the genera Rafinesquina and Cincinitina, pre-invasion specimens inhabit a larger proportion of morphospace, with more specimens exhibiting an ovular outline. Post-invasion specimens contract in morphospace, exhibiting a more rectangular shape. However, Cincinitina is missing from the offshore environment in the C2 sequence and the deep subtidal environment in the C5 sequence, making it difficult to distinguish the effects of invasion from ecophenotypic variation.

Ultimately, our study demonstrates that SfM makes gathering 3D morphological data from the field possible. Because this is a low-cost and easily accessible method, possibilities of applying it more broadly within paleobiology abound. Further development of this technique will not only provide a better understanding of the distribution of morphological form within stratigraphic architecture, but also increase the quantity of morphological data from key intervals throughout the Phanerozoic. These data can be stored as a digital archive that could facilitate large-scale meta-analyses as well as education and outreach activities.

How to cite: Sclafani, J., Christie, M., Cone, M., Roselle, B., Bourne, A., Gazze, C., and O'Brien, M.: Morphology in time and space: how does shape change with sequence stratigraphic architecture?, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-832, https://doi.org/10.5194/egusphere-egu2020-832, 2019

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