Permian Fossil Cluster 1.87" Lower Permian Fissure
Permian Fossil Cluster 1.87" Lower Permian Fissure
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This incredible matrix fossil cluster contains Permian Period material that is estimated to be 286,000,000 years old. This chapter in life's evolutionary history marked the rise of amniotes, egg-laying animals that came to dominate the surface of the Earth long before the dinosaurs.
This specimen is a 1.87" cluster of Permian material recovered from the Lower Permian Fissure near Lawton, Oklahoma. It contains a fossil material from an unidentified tetrapod.
📸 A sample permian cluster
A Strange Prehistoric World
Millions of years before the dinosaurs, our planet was populated with a vast array of even stranger creatures. Land vertebrate species underwent an evolutionary boom and grew into an incredible menagerie of new forms. During this brilliant period of life we call the Permian, gliding animals, powerful beasts, and egg-laying creatures rose to prominence. The world was changing and growing into something beautiful.
These fascinating showcase specimens are clusters of small Permian bones held in a fossilized matrix. Each cluster contains a unique variety of bones from different animals, most commonly tiny teeth and leg bones from fish and tetrapod reptiles. Our material was recovered from the Richards Spur Quarry near Lawton, Oklahoma, and Archer County in Texas. It is estimated to be 286,000,000 years old.
Each Permian fossil cluster has been photographed individually and listed by size in the collection below. They ship in a sturdy carton along with a certificate of authenticity.
Dimetrodon Spine Sail Fragments
Dimetrodon Spine Sail Fragments
📷 An artistic rendition of Captorhinus, a Permian Tetrapod
More About The Permian Period
📸 A sample Permian Cluster specimen
The Permian Period began around 298 million years ago, after the end of the Carboniferous. It was a transition from warm, swampy jungles towards a more arid climate. The supercontinent Pangea had formed into the single landmass on the planet, with an interior that held stretches of dry deserts within. This was coupled with sudden and extreme weather changes from the Panthalassic Ocean that resulted in frequent “megamonsoons" bringing powerful rain seasons to the coasts.
This was the stage on which Permian creatures thrived. Egg-laying animals called amniotes were among the most prolific groups to be found. The emergence of eggs gave them an edge over amphibians, as they could hatch their young on land and away from aquatic predators. With the arrival of amniotes, life’s dependence on the oceans was severed.
📸 Sketches of a Captorhinus skull, an early sauropsid reptile from the Permian. (Image Credit: Bookend/Alamy)
Amniotes are split into two main groups: synapsids and sauropsids. These types of creatures were both quite fast on land, and both had members that were capable of flight. The main difference was in their skulls, with synapsids having a single temporal fenestra (an opening in the skull behind the eye) and sauropsids having two, or none at all.
The synapsids' ability to thermoregulate was perfectly suited to the challenges of the surface and its climate fluctuations. Synapsids of all shapes and sizes could be found living during this period, from the sail-backed Dimetrodon and the tusked Dicynodonts, to tiny tetrapods. While sauropsids were less successful, they still emerged with plenty of unique species, such as the bumpy tetrapod Pareiasaurus and the early gliding vertebrate, Weigeltisaurus.
📸 A permian fossil cluster in hand
Synapsids would not rule the Earth forever. The end of the Permian saw the largest mass extinction event of all time, the Great Dying. Over 1 million years, basalt eruptions in what is now Siberia skyrocketed carbon dioxide, methane, and temperatures. Over 95% of life on the planet was killed.
The surviving Sauropsida species eventually evolved into archosaurs, the early ancestors of the dinosaurs. Synapsids survived, but were overtaken by their reptilian competitors, evolving to fit a smaller, nocturnal niche as mammals.
Further Reading
Anderson JS, Bolt JR. New Information on Amphibamids (Tetrapoda, Temnospondyli) from Richards Spur (Fort Sill), Oklahoma. Journal of Vertebrate Paleontology. 2013; 33(3): 553-567. doi:10.1080/02724634.2013.726676
Bazzana, Kayla D. et al. “Endocasts of the Basal Sauropsid Captorhinus Reveal Unexpected Neurological Diversity in Early Reptiles.” The Anatomical Record. (Hoboken, N.J. : 2007) 306.3 (2023): 552–563.
Giles, Jessica M et al. “Lakes, Loess, and Paleosols in the Permian Wellington Formation of Oklahoma, U.S.A.; Implications for Paleoclimate and Paleogeography of the Midcontinent.” Journal of Sedimentary Research. 83.10 (2013): 825–846.
Bazzana, Kayla D., et al. "Endocasts of the basal sauropsid Captorhinus reveal unexpected neurological diversity in early reptiles." The Anatomical Record. 306.3 (2023): 552-563.
DeBraga, Michael, Joseph J. Bevitt, and Robert R. Reisz. "A new captorhinid from the Permian cave system near Richards Spur, Oklahoma, and the taxic diversity of Captorhinus at this locality." Frontiers in Earth Science. 7 (2019): 112.