Montana’s Cambrian Rocks Part II

Nerds in a bar, volume 4. Dick Gibson sits down with geologist Katie McDonald to talk about some of the interesting details of the Cambrian rocks of Montana, and the unresolved problems they pose for the geologic history of western North America. This discussion builds on the outline in the podcast on February 22.

February 22. Cambrian Stratigraphy of western Montana

When I was a student at Indiana University’s geology field course, out here in Montana, we learned the stratigraphic section.

The Cambrian part is Flathead-Wolsey-Meagher-Park-Pilgrim. The Flathead is the oldest layer of the Cambrian out here, and I hope you aren’t surprised to learn that it’s a clean quartz sandstone like the Tapeats in the Grand Canyon and the Posdam back east. Like them, the Flathead sandstone sits above a profound unconformity, a break in the rock record, and the rocks below it are Precambrian in age, hundreds of millions of years older than the Flathead. It’s pinkish, like the Potsdam, because of some iron oxide cement, and it has little round green grains in it in places – we’ll talk about them tomorrow – but mostly, it’s just nice sandstone.

Trilobite Bathyuriscus formosis, Cambrian Meagher formation, Montana.
Photo by Stephen W. Henderson, used by permission.

The stratigraphic section here in Montana is a lot like the Cambrian section in the Grand Canyon. Above the Tapeats sandstone in the Grand Canyon we have the Bright Angel Shale, followed by the Muav limestone. Here in Montana, the Flathead sandstone is followed by the Wolsey Shale, then the Meagher Limestone. Then the Park Shale, and then the Pilgrim formation, limestones and dolomites.

The seas came in, the seas came out…. Alternating shale and limestone might mean that, but there are other ways to make it happen. I’m planning to have a conversation with an expert on Cambrian stratigraphy in a week or so – we might be in the Ordovician by then, but if we are we’ll just think back on the Cambrian when that conversation happens.

From the point of view of someone mapping geologic layers, the importance of the sequence – Flathead, Wolsey, Meagher, Park, Pilgrim – is that it’s really the best way, sometimes the only way, to be sure which rock or rocks you might be looking at. In western Montana, there’s another pinkish quartz sandstone called the Quadrant – a chunk of it looks an awful lot like a chunk of the Flathead, to the point that it’s virtually impossible to tell them apart in the field. But the Quadrant is Pennsylvanian in age, around 280 million years old, rather than around 500 million years for the Flathead.  If you look at the rocks below the Quadrant, you won’t find the Precambrian unless there’s some complicated structural thing going on, like faulting. And if you look above, you won’t find the precise sequence of the Wolsey, a specific kind of shale, the Meagher, a limestone with distinctive characteristics, the Park shale, and then the Pilgrim formation. It’s that sequence that’s like a fingerprint that tells you you’re in the Cambrian, even if the individual chunks of rock can’t tell you that for sure.

—Richard I. Gibson

Trilobite Bathyuriscus formosis, Cambrian Meagher formation, Montana. Photo by Stephen W. Henderson, used by permission.

February 11. The concept of stratigraphy

Today I thought we’d talk a bit about the concept of stratigraphy, some ideas that will help with understanding of the geologic events we’re talking about.

Steno

Stratigraphy is the study of strata, or layers within the earth. Stratum, the singular of strata, comes from Latin for a bed, and ultimately from a word meaning to spread out—and that's what geological strata do: they spread out over wide areas. The science focuses mostly on sedimentary layers, beds of sandstone, shale, limestone and so on. One key aspect of stratigraphy is the law of superposition – an fancy way of saying that lower layers are older than higher layers. This may seem obvious – if it doesn’t, think about throwing some red sand into a pail on Wednesday, then on Thursday come back and throw in some lime. The sand is older than the lime. It was not obvious to early scientists, and it was Nicholas Steno, a Danish Catholic Bishop, who lived in the 1600s and pioneered and promoted this and other basic aspects of geology. He also conceived the principle of original horizontality, which says that layers of sediment – sand, silt, mud – were laid down in horizontal layers under the action of gravity. There are some obvious exceptions to this, such as deposits on mountain or undersea slopes, but it’s a general principle that matters greatly when we look at rocks that have been deformed by faulting or folding.

Smith

If you’re interested in Steno’s story, I can recommend a book by Alan Cutler called The Seashell on the Mountaintop.

While in many ways Steno was the father of stratigraphy, the one who really implemented stratigraphic ideas in a modern way was a British surveyor, William Smith. To this day I still think of him as William “Strata” Smith, as he was called when I first took physical and historical geology classes back in the 1960s. He recognized that different layers or strata of rocks had distinct fossil assemblages, and that he could recognize those characteristic fossils to help him identify the rock packages elsewhere, even if they were distant and disconnected from the original rocks. And even if the kind of rock changed. That meant that the same kinds of fossils, in a sandstone here, but in a limestone there, meant those diverse rocks were of the same age.

Smith made the first geologic map of England and Wales, published in 1815. That was The Map that Changed the World, in the title of the book by Simon Winchester that recounts Smith’s story.

—Richard I. Gibson

The "map that changed the world"