Region 3: The Coastal Plain

After the breakup of Pangaea during the Mesozoic, the North American plate drifted away from the Mid-Atlantic Ridge. Decreased tectonic activity along the continent’s eastern and southeastern edge led to the formation of a passive continental margin. The Coastal Plain extends along this margin, across the Gulf of Mexico and up through the Mississippi Embayment.

The sediment and rock of the Coastal Plain is geologically very young, ranging in age from the Cretaceous to the present (Figure 2.12). The region’s sediment and rock include gravel, sand, silt, clay, marl, limestone, and uncommon layers of concentrated shell material called coquina. Much of the Coastal Plain’s “rock” is actually unconsolidated sediment that has not had enough time to be lithified, cemented, or sufficiently compacted into hard rock. Coastal Plain sediment forms a wedge of gently dipping layers of sediment and sedimentary rock that thickens towards the Gulf of Mexico, overlying older bedrock (Figure 2.13). This sediment is 6100 meters (20,000 feet) thick in northern Louisiana, thickens to 12,000 meters (40,000 feet) at the coast, and reaches 18,000 meters (60,000 feet) offshore. Depending on the rates of cementation or compaction, it may take tens or even hundreds of millions of years before these layers of sediment are lithified.

Figure 2.12: Generalized geologic map of the Coastal Plain.

Figure 2.12: Generalized geologic map of the Coastal Plain.

Figure 2.13: Millions of years of sediment accumulation in the basins caused coastal areas to subside, creating a gentle slope toward the Gulf of Mexico.

Figure 2.13: Millions of years of sediment accumulation in the basins caused coastal areas to subside, creating a gentle slope toward the Gulf of Mexico.

Figure 2.14: Shoreline positions along the Coastal Plain during the past 70 million years.

Figure 2.14: Shoreline positions along the Coastal Plain during the past 70 million years.

The Coastal Plain surface and subsurface sediments of Arkansas, Missouri, and Louisiana are dominated by those deposited in alluvial or deltaic settings. This indicates that a major river system, such as the Mississippi, has existed since the initial formation of the Gulf of Mexico (which occurred during the breakup of Pangaea in the Mesozoic). A progression of fluvial, deltaic, and coastal deposits carrying sediments eroded from the Ouachitas has migrated into the Gulf over time, continually altering the coastline (Figure 2.14).

The state of Louisiana formed as a slow regression in sea level allowed the deposition of sediment to create a terrestrial environment at the edge of the Gulf. Approximately 25% of the state’s northern surface, consists of Paleogene- and Neogene-aged shales, sandstones, and gravels deposited within fluvial, deltaic, and shallow marine settings (Figure 2.15). The remaining 75% of the surface consists of Quaternary-aged silts, sands, and gravels deposited from channels, marshes, levees, and terraces.

Thousands of feet of salt are present under the fluvial deposits of the Mississippi. This thick layer of salt accumulated during the initial formation of the Gulf when flooding and evaporation occurred during the early stages of Pangaea’s breakup. Since the salt deposits are less dense than sandy and muddy sediments, they moved plastically and vertically to form salt domes, some of which reach to and are exposed at the surface today. Louisiana’s few Cretaceous-aged outcrops, in Bienville Parish, consist of older marine deposits that were uplifted by the formation of these salt domes.

Figure 2.15: The Kisatchie National Forest in north-central Louisiana contains some of the state’s oldest sediment, including Paleogene and Neogene silt, gravel, and shale.

Figure 2.15: The Kisatchie National Forest in north-central Louisiana contains some of the state’s oldest sediment, including Paleogene and Neogene silt, gravel, and shale.

In Texas, the Coastal Plain is subdivided into several physiographic provinces (Figure 2.16). The Coastal Prairies along the Gulf of Mexico are dominated by Pleistocene deltaic sands, silts, and clays. Ever since our modern sea level was reached some 3000 years ago, thin coastal-barrier, lagoon, and delta sediments have been deposited along the Coastal Prairies. Further inland, along the Interior Coastal Plains, Cenozoic clay, shales, and uncemented sands are present, overlying Pliocene limestone. In the innermost part of the Coastal Plain (the Blackland Prairies), chalks and marls are present.

See Chapter 4: Topography to learn more about salt domes and the formation of the Coastal Plain.

The Balcones Escarpment forms the western boundary of Texas’ Coastal Plain, and extends from approximately Dallas to San Antonio. It is the surface expression of the Balcones Fault—a fault system that is thought to have formed 300 million years ago during the Ouachita Orogeny. The escarpment features cliffs that expose walls of Cretaceous limestone (Figure 2.17), as well as subterranean caves. The rocks to the west of the Balcones Escarpment are more resistant to erosion than the soft sediments of the Coastal Plain are; as a result, erosion and weathering have served to accentuate the Escarpment’s height (Figure 2.18).

Figure 2.16: Physiographic map of Texas.

Figure 2.16: Physiographic map of Texas.

Figure 2.17: Faulted Cretaceous limestone is exposed along the Balcones Escarpment at a roadcut on US 281 North.

Figure 2.17: Faulted Cretaceous limestone is exposed along the Balcones Escarpment at a roadcut on US 281 North.

Figure 2.18: The Balcones Escarpment and its surrounding environments have been shaped by erosion.

Figure 2.18: The Balcones Escarpment and its surrounding environments have been shaped by erosion.