Figure 1. Tectonic Map of Texas.
LAB 1. TECTONIC STRUCTURES OF TEXAS
This lab introduces the large-scale tectonic structures of Texas by examining aspects of the geological evolution of the state over time, from the Precambrian (approximately 1.1 billion years ago) to the present-day.
Figure 1. Tectonic Map of Texas.
The Llano Uplift.
Precambrian rocks of the North American craton are exposed in only a few places
in Texas. The most prominent, and a dominant geologic feature of the state (Fig.
1), is
the Llano Uplift in the center of the Texas Hill Country. Part of the Llano
Uplift forms Enchanted Rock - a granite exfoliation dome (Fig. 2).
Figure 2. Enchanted Rock. This Precambrian granite (1.1 billion years
old) is part of the North American craton exposed in the Llano
Uplift.
It appears that the craton is thicker here than in the surrounding region. This is why this part of the state is an "uplift" (the thicker continental crust "floats" higher on the underlying mantle).
The Ouachita Tectonic Front.
The Ouachita Tectonic Front is an orogenic belt formed during the Ouachita
Orogeny (Fig. 1). This orogeny resulted from the collision of North America and
South America in the late Paleozoic Era (about 290 million years ago). The
collision formed a large mountain chain along the southern margin of North
America (Fig. 3).
Figure 3. The collision of North America and
South America about 290 million years ago.
Although much of these mountains are now eroded and buried, remnants form the Ouachita Mountains of Arkansas/Oklahoma and the Marathon Mountains of Texas (Fig.4).
Figure 4. Shaded Relief Image of Texas. OM: Ouachita Mountains; MM: Marathon
Mountains; EP: Edwards Plateau; B&R: Basin and Range; PB: Permian Basin; LE:
Llano Estacado
The Balcones Escarpment.
The Balcones Escarpment separates the uplifted region to the northwest of
the Balcones Fault Zone from the subsided region to the southeast (Fig. 1).
Vertical displacement between these two regions has occurred along a series of
high-angle normal faults that probably formed during the Ouachita Orogeny, the
rifting of North and South America following the orogeny and subsidence of the
Gulf Coastal Plain due to sediment loading. In general, rocks to the northwest
of the escarpment are more resistant to erosion than rocks to the southeast and
so differential erosion also has played a role in creating about 300 feet of
elevation change across the escarpment (Fig. 5).
Figure 5. Satellite view to the southwest across Texas, showing Austin (A) and
San Antonio (B) at the base of the Balcones Escarpment (arrowed). Corpus Christi is seen
in the distance (C).
The Edwards Plateau.
The Edwards Plateau (Fig. 4) is capped by hard Cretaceous limestones. Some
of the relief of this region is due to uplift along the Balcones Fault Zone,
some is due to the resistance of the limestones to erosion (Fig. 6).
Figure 6. View from the top of Enchanted Rock. Precambrian granite outcrops are
seen to the right; the far horizon (EP) is the edge of the Edwards Plateau
(Note: the Llano Uplift is exposed in a topographic basin within the Edwards
Plateau).
The Permian Basin.
During the Permian Period, about 280 million years ago, the Ouachita
mountains bordered the eastern margin of several inland marine
basins, including the Midland, Delaware, and Palo Duro
basins (Fig. 1), which now collectively compose the oilrich Permian
Basin of West Texas (Fig. 4, PB; Fig. 7). These basins filled with marine, fluvial,
deltaic and
evaporite deposits, including gypsum (Fig. 8).
Figure 7. View of the Guadalupe Mountains on the
Texas/New Mexico border from the Permian Basin. The mountains are a fringing
limestone reef that surrounded an inland sea.
Figure 8. Road cut exposing gypsum deposits in the
Delaware Basin.
The Basin and Range.
Far west Texas lies in the Basin and Range Province of western North
America. This region (Fig. 4, B&R) is part of the Laramide Tectonic Front.
This orogeny, resulting from plate convergence along the western margin of North
America, formed many of the major structures of the Rocky Mountains during the
early Tertiary Period (30-60 million years ago). Orogenic activity also led to
the emplacement of many volcanic rocks in the Big Bend region and the formation
of numerous faults - movement along these faults created the basin and range
topography (Fig. 9).
Figure 9. Numerous fault-block ranges (uplands) in Big Bend National Park.
Llano Estacado.
During the middle to late Cenozoic Era (5-30 million years ago), streams originating in the recently elevated Rocky Mountains to the west transported large
volumes of sand and gravel into the Texas Panhandle, which accumulated in large alluvial
fans - an example of backarc basin sedimentation. These deposits form the
Southern High Plains (Llano Estacado) - a nearly flat plateau with an average elevation approximating 3,000
feet (Fig. 4, LE). Between 5 and 10 million years ago, the sediment supply was
cut off due to regional uplift in the west and the eastern edge of the plains began to retreat westward as rivers draining into the Gulf of Mexico caused headward
erosion, as exemplified by Palo Duro Canyon. The resulting escarpment that extends in a northsouth line in West Texas and the Panhandle is the
Caprock Escarpment (Fig. 10). To the west, the Llano Estacado is bounded by the Mescalero
escarpment, overlooking the Pecos Valley (Fig. 11).
Figure 10. The Caprock Escarpment in the Texas Panhandle. The Llano Estacado lies
to the left (west), numerous canyons and gullies mark the Caprock Escarpment and
the eroded plains to the right (east).
Figure 11. The Mascalero Escarpment on the western edge of the Llano Estacado in
New Mexico.
The Gulf Coastal Plain.
The Gulf Coastal Plain (Fig. 1) consists mainly of Tertiary clastics (mud
and sand) and is an example of passive margin sedimentation. Numerous faults
parallel the coast, formed partly by rifting as North and South America
separated after the Ouachita Orogeny, partly by Tertiary sediment loading (Fig.
12).
Figure 12. Cross section of south Texas from the
Llano Uplift to the Gulf of Mexico. LU: Llano Uplift; OOB: Ouachita Orogenic
Belt; BFZ: Balcones Fault Zone; T--->: Base of Tertiary sedimentation; C:
coastline. Numerous high-angle faults cut the section (lines with arrows). Green
columns are salt domes.