Fossil Fly from Kemmerer, Wyoming #2
Fossil Fly from Kemmerer, Wyoming #2

Fossil Fly from Kemmerer, Wyoming #2

This piece is not for sale.

AGE: 52-Million-Years-Old

Location: Kemmerer, Wyoming

  Self collected in May, 2018! 

Story of the Green River Formation

Rocks of the Green River Formation contain a story of what the environment was like about 50 million years ago in what is now parts of Colorado, Utah, and Wyoming (see map below). At that time, forces within the Earth were almost finished with the job of uplifting the Rocky Mountains, and the landscape consisted of rugged mountains separated by broad intermountain basins.

Streams draining the steep mountains carried large amounts of sand, silt, mud and dissolved minerals into lakes that occupied the intermountain basis. Over time the sand, silt and mud began infilling the lakes. The dissolved minerals altered the chemistry of the lake waters. Abundant plants grew on broad swampy areas that developed around the margins of the lakes.

Oil Shales and Coals

The Green River climate was moist and warm - perfect for rapid plant growth. This allowed a dense community of plants to spread across the swampy areas along the lake margins. These plants dropped a steady supply of leaves, branches, seeds and woody materials into the swamp waters. The water cover of the swamp protected the plant debris from decay and it accumulated rapidly. The plant debris layers grew thicker and more extensive over time. Eventually the layers of plant debris were buried and transformed into coal seams.

Conditions in the lakes were also ideal for thriving blooms of blue-green algae. They spread over many parts of the lakes as a thick scum of green filaments and strands. For several million years enormous amounts of algal debris sank to the bottom and were incorporated into the lake sediments. Through time the algae-rich sediments were transformed into the largest oil shale resource on Earth.

Varved Sediments

In some parts of the lakes, sediments were deposited in very thin layers known as varves (see photo). A thin layer of dark-colored sediment was deposited during the growing season, and a thin layer of light-colored sediment was deposited in winter. The varves ranged in thickness from a fraction of a millimeter to a few millimeters each. Some of the most detailed and highly preserved fossils are contained in varved sediments composed of very fine-grained lime mud. When these thinly layered rocks are split, the smooth bedding surfaces often reveal a delicately-preserved fossil. Millions of Green River fossils have been collected by amateur and professional collectors. They are now in collections, exhibits and museums around the world. Photographs of a number of specimens are presented on this page. These photographs are from the archive of the National Park Service.

The Green River Formation is best known among paleontologists for its superbly preserved fossil fish. Some slabs of the Green River Formation contain hundreds of individual fish and likely represent an instantaneous die-off. Dozens of fish species have been identified. One species, Knightia, a small fish usually less than six inches in length, is especially common. Specimens of Knightia have made their way into thousands of fossil collections around the world.

An abundance of fossil plants have been found in sediments that accumulated along the edges of the lake. Palm leaves, ferns, and sycamore leaves are very common fossils of these Green River swamp sediments. Fossil of turtles, bats, birds, mammals, snakes, and crocodiles have also been found in the Green River Formation.

Age of the Green River Fossils

Determining an accurate age for a rock unit can be very difficult. However, rocks of the Green River Formation have been dated to within a few million years through the analysis of volcanic mineral grains.

Volcanoes in what is now Yellowstone to the north and the San Juan volcanic field to the south produced occasional ash clouds that dropped thin layers of volcanic ash into the calm lake waters. These ash layers were preserved and contain tiny mineral grains that crystallized during the volcanic eruption. Researchers have collected samples of these ashfall layers and through analysis have determined the crystallization date of the tiny volcanic grains. They indicate that the lakes are about 50 million years old and span a time interval of several million years during the early to mid Eocene Epoch.