GSA Connects 2023 Meeting in Pittsburgh, Pennsylvania

Paper No. 58-12
Presentation Time: 4:40 PM

CONNECTING EARLY PALEOZOIC ECHINODERM DIVERSITY DYNAMICS TO SHIFTING CLIMATE PATTERNS


HARRIS, Ohav B., The University of South Florida, 4202 E Fowler Ave NES 207, Tampa, FL 33620-0001, SHEFFIELD, Sarah, School of Geosciences, University of South Florida, 4202 E. Fowler Avenue, NES 107, Tampa, FL 33620-5550, LAM, Adriane R., Department of Earth and Planetary Sciences, University of Tennessee, 602 Strong Hall, 1621 Cumberland Avenue, Knoxville, TN 37996, BAUER, Jennifer E., Museum of Paleontology, University of Michigan, Research Museum Center, Suite 1820, 3600 Varsity Drive, Ann Arbor, MI 48108, DELINE, Bradley, Department of Natural Sciences, University of West Georgia, 1601 Maple St, Carrollton, GA 30118 and LAMSDELL, James C., Department of Geology & Geography, West Virginia University, Morgantown, WV 26505

The Paleozoic Era was host to many significant biotic events such as the Great Ordovician Biodiversification Event, the Late Ordovician Mass Extinction, and the Late Devonian extinctions. These events were likely catalyzed by abiotic (e.g. climate) versus biotic drivers. Echinoderms are globally distributed, temporally expansive, and easily identifiable; these qualities make them an excellent model system to test hypotheses relating biodiversity with abiotic factors. Biodiversity patterns of echinoderms are currently not well understood because of a lack of focus on the dynamics of the entire clade. To remedy this, we have worked to expand current understandings of Paleozoic echinoderm diversity patterns by investigating the global distribution and temporal occurrences of taxa spanning the entire clade. Results suggest patterns of diversity unique to previously established trends that predominantly centered on a limited number of echinoderm groups.

To examine the connection between climate change and Paleozoic echinoderm biodiversity (i.e., diversification, extinction, and origination rates), we collated stable oxygen isotope data from the primary literature spanning the Ordovician to the Devonian. We compiled these data to create a continuous curve of δ18O values during the described period to better evaluate in tandem with echinoderm diversity metrics. When the δ18O curve is compared to the echinoderm biodiversity patterns, we found that cooling periods coincide with increased extinction rates, corroborating prior hypotheses that major end-Ordovician cooling triggered changes in echinoderm biodiversity at a global level and further identifying a potential pattern in abiotic drivers in echinoderm biodiversity. The connection between Paleozoic echinoderm biodiversity and other abiotic factors will be further studied by comparing these recovered patterns with paleolatitudinal distributions.