“Living on a layer cake
Way down under the ground
Living on a layer cake
Take a slice and look around.”
Way down under the ground
Living on a layer cake
Take a slice and look around.”
(Chris Rawlings)
Growing up
in Kansas I was quite used to term “layer cake geology”—the rocks are
relatively flat, at least on the surface, and it is fairly easy to predict the
ages of outcrops. After stripping off
the glacial debris in the northeastern one-fifth of the state, one finds the
youngest rocks in the west and the oldest in the eastern part of the state. As
an example, in driving I-70 from the Colorado-Kansas line east to Kansas City
the traveler would traverse rocks ranging from the Pleistocene/Holocene sediments
and late Cenozoic Ogallala Formation through a nice section of Cretaceous
rocks, to fantastic exposures of fossiliferous Permian (the Flint Hills) and
Pennsylvanian rocks (Osage Cuestas).
Triassic and Jurassic strata are missing (on the surface) and the oldest
rocks cropping out in Kansas are of Mississippian age in the extreme
southeastern corner. One must look in
the subsurface to locate older rocks.
The traveler also will not notice any appreciable tilting of the
beds---layer cake geology at its best; however, erosion by streams has produced
fine exposures.
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Generalized
geologic map of Kansas showing outcrops of Cenozoic (C), Cretaceous (K), Permian (Pm), Pennsylvanian (P), Mississippian (M), glacial (G). Map courtesy of Kansas Geological Survey.
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You can
imagine my surprise, then, on my first trip to Colorado (in grade school) when
I noticed that some rock layers were not flat but were actually “standing
up”! How in the world did that happen? In the pre-internet days the only possibility
for an answer was waiting until school started in the fall and then consulting
an ancient set of “encyclopedias”.
In the
meantime, I continued to collect rocks and minerals with the most interesting specimens
being those from local sand and gravel quarries. Little did I realize that “those most
interesting” minerals (mostly jasper, chert, and quartz) had a source area near
the “standing up rocks”. At any rate, I
was hooked on geology.
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TWO
roads diverged in a yellow wood,
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And
sorry I could not travel both
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And
be one traveler, long I stood
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And
looked down one as far as I could
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To
where it bent in the undergrowth;
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Then
took the other, as just as fair,
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And
having perhaps the better claim,
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Because
it was grassy and wanted wear;
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Though
as for that the passing there
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Had
worn them really about the same,...
Today
(August 2015) I thought about this early Colorado trip in relationship to an
NPR story about Robert Frost and his most famous poem—The Road Not Taken. I
don’t know about schools today but virtually every kid in my time studied the
poem in English class(es). The poem
reminded me of, not two roads diverging, but two layers of rocks
diverging--one being flat the other bending.
I know, strange analogy, but that is the way my mind works!
What I
did find in the “encyclopedia” was that mountain building, and igneous rock
events, pushing up from below, had tilted and bent the overlying sedimentary
rocks. Of course, in the days before
our understanding of plate tectonics the “encyclopedias” really did not
explain how these mountains formed. As
I grew older, and with an additional understanding of geology, I became
fascinated with the bending and folding of rock layers, especially those that
formed topographic or geographic features.
Colorado
and the Mountain West are fortunate to have a wide variety of folded rocks
that are described by Matthews and others (2003) as “metamorphic folds,
basement cored folds, salt-cored folds, monoclines, syn-depositional folds,
anticlines, synclines, domes, basins, refolded folds, evaporate-flowage
folds, collapse folds, disharmonic folds, and forced folds”. This small article will focus on some of
the larger geographic features that readers might locate.
Anticlines
are folds where the limbs dip away from the axis (convex-up) and where the
oldest rocks are in the center of the fold.
The cartoon above shows a nice symmetrical fold while in reality most
anticlines are asymmetrical, plunging, or even overturned. In addition, erosion often planes off the
top of the structure so that the fold does not form a topographic high and
one must examine geologic maps and/or aerial photos to determine size and
extent. A structural high (anticline)
does not always produce a topographic high (hill/mountain). At other times the structure is quite
visible as resistant rocks in the limbs form an impressive outline of the
fold. Most anticlines in Colorado are
the result of compression associated with the Laramide Orogeny (building of
Rocky Mountains). Imagine piling
several carpets, of different colors, on top of each other and then pushing
them against a wall. The carpets would
“bulge up” into several “anticlines” due to the compressive forces.
Many of
the larger mountain ranges in Colorado, such as the Front Range, are actually
large anticlines where steeply dipping sedimentary rocks are exposed along
the flanks and Precambrian basement rocks crop out in the center of the
fold. The original extent of the
sedimentary rocks was “over” the Precambrian rocks; however, with uplift the
sedimentary rocks were eroded off the top.
Geologists often term this type of large fold as a “basement-cored
anticline”. The Black Hills of South
Dakota represent a miniature version of a Laramide basement-cored anticline
and one that is easy to see and understand.
Here in South Dakota vertical movement has produced a topographic high
corresponding with a structural high.
In the Black Hills, at the center of the anticline (sometime referred
to as a dome), are rocks of Precambrian age.
As one moves out from the center the sedimentary rocks of Paleozoic
and Mesozoic age grow progressively younger.
What makes the Black Hills nice to study is the lack of large faults
that often complicate the geological understanding of Colorado’s mountain
ranges.
Smaller
anticlines (non-basement-cored), also due to compression and folding, are
often found off the flanks of the mountain folds. One of my favorite vest pocket anticline is
Split Mountain at Dinosaur National Monument along the CO-UT state line, a
fold associated with the much larger Uinta Mountain Range. At Split Mountain
the Green River cuts a fantastic canyon right through the heart of the
anticline and a raft ride takes the paddler through both limbs and the core
of the fold.
Some
subsurface anticlines are commercially important as they serve as traps for
petroleum (oil and gas). The Raven
Park Anticline (aka Rangely Anticline), the major petroleum trap at the giant
Rangely Field in northwestern Colorado, was discovered in 1901 and has
produced between 800-900 million barrels of oil, mostly from the Weber
Sandstone at subsurface depths of ~6400 feet.
Secondary Recovery (water injection) started in 1957 while Tertiary
Recovery (injection of CO2)
commenced in 1986 and the anticline is still producing. It is
interesting to note that the Weber is subsurface at Rangely but is well
exposed and surficial at Dinosaur National Monument, a mere ~30 miles
away.
Synclines
are the opposite of anticlines with the limbs dipping toward the center of
the axis, convex-down, and where the youngest rocks are in the center of the
fold. Most synclines associated with
the Colorado mountains are small in stature and rarely form topographic
features. The Cub Creek Syncline at
Dinosaur National Monument is an easy fold to observe.
Large
scale basins are the opposite of the basement-cored anticlines and include
Laramide features such as the Denver-Julesburg Basin east of the Front Range
(70,000sq. mi.) and the Piceance Basin in northwest Colorado. Both of these are structural basins (large
synclines) and do not form topographic lows and therefore do not show up as
“landscape features”. There is a
formation elevation change (in the subsurface) of about 9000 feet from the
edge of the Denver-Julesburg Basin to the center.
The last
type of the major folding structures is the monocline, often described as
“half an anticline”—there is only one dipping limb coming off flat or
horizontal layers. The Colorado
Plateau has some of the most impressive monoclines in the world with the
“bend” commonly associated with subsurface faulting in the underlying
Precambrian rocks. Monoclines at
Colorado National Monument and Dinosaur National Monument are especially
impressive.
This small article cannot begin to cover all of
the standing, contorted, disturbed, folded, and bent rocks in Colorado. Virtually any of the rocks in the western
one-half of the state are folded and faulted and a drive on most of the roads
leading west will reveal some of the magic.
Purchase a geologic map from the State Survey and take a road trip!
As for my circuitous route from Kansas to Colorado—I came here from the city, a thousand
miles away; Now I sing a mountain song of the night wind in the pines; I've
seen the quiet splendor of a field of columbine (The Mountain
Song; John Denver).
REFERENCES CITED
Matthews,V., K. KellerLynn, and B. Fox. 2003. Messages in Stone. Denver: Colorado
Geological Survey.
Strahler, A. N., and A. H. Strahler. 1978. Modern
Physical Geography. New York: John Wiley & Sons.
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