Any boomer, gen xer, millennial, gen zer or alpha who’s studied geology has likely gained foundational knowledge from Edwin Dinwiddie McKee’s landmark studies of the Grand Canyon’s sedimentary record – even if they don’t readily recognize McKee’s name.
The legendary scientist, who lived from 1906-1984, studied and documented the stratigraphy and sedimentation of Colorado Plateau geology, especially the Grand Canyon’s Cambrian Tonto Group, for more than 50 years. His time-tested tenets have influenced generations of geoscientists.
“The Tonto Group holds a treasure trove of sedimentary layers and fossils chronicling the Cambrian Explosion some 540 million years ago, when the first vertebrates and animals with hard shells rapidly proliferated and sea levels rose to envelope continents with emerging marine life,” says Carol Dehler, professor at Utah State University. “McKee marveled at this pivotal geologic period, yet had no knowledge of plate tectonics or global sea level change, and his ideas were often shunned by the scientific community of the time.”
Yet, what if McKee could have fast-forwarded through time and availed himself of current-day stratigraphic, depositional and paleontological models, data and technological muscle?
Dehler, with colleagues James Hagadorn of the Denver Museum of Nature & Science, Frederick Sundberg, Karl Karlstrom and Laura Crossey of the University of New Mexico, Mark Schmitz of Boise State University and Stephen Rowland of the University of Nevada, Las Vegas, along with their students and interns, have employed these tools to construct an updated and insightful framework of McKee’s foundational ideas. They report their efforts in “The Cambrian of the Grand Canyon: Refinement of a Classic Stratigraphic Model,” the cover story of the November 2024 print issue of the Geological Society of America’s GSA Today journal, published online.
The team’s research was supported by a National Science Foundation Division of Earth Sciences grant.
“The Grand Canyon is an epic Rosetta Stone for geology,” says Hagadorn, Tim & Kathryn Ryan Curator of Geology at DMNS. “And we’re helping to further decode it. Because Grand Canyon rocks record global changes in climate and tectonics, our work help us understand strata that were deposited worldwide during the Cambrian period.”
Studying the Tonto Group, he says, is like being a detective at a crime scene.
“You can see clues and discern at least part of what happened,” Hagadorn says. “But determining how it happened and the sequence of events takes time and effort. Just like the scene of a crime, the rock record of the Grand Canyon is much more complicated than what we currently know and its story is still being written.”
Dehler says the team’s new model offers three key pathways for deeper understanding.
“From the Tonto Group’s 500-meter-thick strata, we’re learning about sea-level rise and the effects of catastrophic tropical storms – probably more powerful than today’s devastating hurricanes – during a period of very hot temperatures when the Earth was ice-free,” she says.
Sea levels were so high during this time period, Dehler says, that rocks like the Tonto Group were deposited atop every continent on Earth, as seas bathed the continents in a complex mosaic of shallow marine, coastal and terrestrial environments.
Further, she says, advanced chronological tools are revealing new information about the tempo of sedimentation, as well as how rapidly trilobites and other “disgusting, cockroach-looking creatures” diversified.
“Our findings are a reminder science is a process,” Hagadorn says. “Our work in the Grand Canyon, one of the world’s most well-known and beloved landscapes, connects people to this science in a very personal way.”