Dinosaur Dung (Coprolite) - Classic Riker Box Specimen
Dinosaur Dung (Coprolite) - Classic Riker Box Specimen
This specimen is a fragment of agatized coprolite from the Morrison Formation in Utah. As pictured, the specimen comes inside a classic, glass-topped riker display case measuring 4 1/2" x 3 1/2". A small information card is also enclosed, which also serves as the certificate of authenticity.
Please Note: The specimens vary in size and color, pictured here are two samples that are around roughly 1" (2.5cm) in size.
πΈ Also Available - Big Poop!
Showcase Specimens
In addition to the classic boxed specimens, we also have large, showcase specimens. Each specimen is pricedΒ and sold individually. As you might expect, these showcase specimens ship in sturdy cartons. They also include individual certificates of authenticity.
ESTIMATED AGE: 150,000,000 YEARS OLD
MORE ABOUT DINOSAUR DUNG
"The Mesozoic trend to sauropod gigantism led to the evolution of immense microbial vats unequalled in modern land animals."
~ David M.Wilkinson, University of Lincoln (2012)
Scientifically speaking, coprolites are fossilized poop. Over millions of years, minerals, such as chalcedony and quartz, replaced the original organic material. This process creates a rich, colorful matrix that allows us to study the diet and lifestyle of long-extinct creatures.
Coprolites can come from reptiles, dinosaurs, and even ancient mammals. Depending on their origin, coprolites may contain a variety of minerals such as phosphorus and calcium. Scientists use these trace fossils to help identify the species responsible for the droppings and to learn more about their diet.
Our specimens come fromΒ the Morrison Formation in Utah. One of the most studied fossil beds of the upper Jurassic Period, the region was once home to a large floodplain ecosystem 150,000,000 years ago. Coprolites of this size are typically attributed to sauropods.
πΈ From "Consumption of crustaceans by megaherbivorous dinosaurs: dietary flexibility and dinosaur life history strategies." Chin, Fledman, Tashman (2017)
WHAT'S INSIDE A COPROLITE?
This image provides incredible detail of several curious samples: (a) conifer wood fragments (b) decayed wood fragment. (c) irregular, knobby cuticle (d-f) cylindrical appendage embedded in coprolitic groundmass (e) thin section of appendage shown in fig d. (f) higher magnification photomicrograph of appendage cuticle in fig d. (g-h) small cuticle fragment (h) Scanning electron micrograph of specimen in (g) revealing perpendicular diagenetic growth of crystals (i-j) Thin section showing a >6 mm long cuticle fragment embedded in fecal groundmass. Yellow rectangle indicates area shown in (i) and blue rectangle shows area of microprobe maps. (j) Close-up image of cuticle in (i). Exocuticle is at right of photo and probable pores are evident. (k-m) distributions of calcium, magnesium, and phosphorus of cuticle in (i). Brighter colours indicate higher element concentrations. Note that distributions of magnesium and phosphorus follow the laminar structure of the cuticle.
Front of the Specimen Card
Back of the Specimen Card
Further Reading
Grove, Richard. The Cambridgeshire coprolite mining rush. Vol. 1. Oleander Press, 1976.
Reinhard, Karl J., and Vaughn M. Bryant Jr. "Coprolite analysis: A biological perspective on archaeology." Papers in Natural Resources. (1992).
Chin, Karen, Rodney M. Feldmann, and Jessica N. Tashman. "Consumption of crustaceans by megaherbivorous dinosaurs: dietary flexibility and dinosaur life history strategies." Scientific reports 7.1 (2017): 11163.
Wilkinson, David M., Euan G. Nisbet, and Graeme D. Ruxton. "Could methane produced by sauropod dinosaurs have helped drive Mesozoic climate warmth?." Current Biology 22.9 (2012): R292-R293.
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