Region 1 & 2: The Central Lowland and Great Plains

See Chapter 1: Geologic History to learn about the Laramide Orogeny and other tectonic events that shaped the face of North America.

The Great Plains and Central Lowland compose a topographically flat expanse that slopes gently eastward toward the mid-continent. Once partly glaciated, these regions are now characterized by rolling, grassy plains and farmland. The land is interrupted only by river and stream valleys and other erosional features formed during the Holocene, with the exception of the Black Hills of Wyoming and South Dakota, and a few outlying Precambrian rocks that protrude through the Quaternary sedimentary cover. Geologically, the Black Hills are the easternmost outpost of the Rocky Mountains and account for considerable mineral wealth in the Great Plains region (Figure 5.1). Beneath the surface cover of Neogene- and late Quaternary-aged sediments lies a series of sedimentary and structural basins formed during the Laramide Orogeny (about 70 to 40 million years ago) and earlier tectonic events preceding the Laramide.

Figure 5.1: Principal mineral resources of the Great Plains and Central Lowland.

Figure 5.1: Principal mineral resources of the Great Plains and Central Lowland.

Large halite deposits that formed nearly 400 million years ago in the warm, evaporating seas of the Devonian are found deep beneath the Williston Basin of North Dakota and Montana. These salt beds represent a massive resource of potash, a name used for a variety of salts containing potassium, with mined potash being primarily potassium chloride. The majority of potash is used as fertilizer, but an increasing amount is being used in a variety of other ways: for water softening, for snow melting, in a variety of industrial processes, as a medicine, and to produce potassium carbonate.

See Chapter 6: Glaciers for more about the effect of glaciers on Great Plains topography.

Several saline lakes (Figure 5.2) on the northern and northwestern plains of North Dakota are “mined” for salts such as sodium sulfate (NaSO4), often in the form of mirabilite (also known as “Glauber salts” in its processed form) (Figure 5.3). This mineral is used in the manufacture of detergents, paper, and chemical processing, especially in the production of hydrochloric and sulfuric acids. The playa lakes that produce these salts were originally potholes created during the last glaciation of North Dakota.

Figure 5.2: A white ring of salt can be seen around the outer rim of this evaporating playa lake in North Dakota. Typically, these shallow lakes fill up with about a foot of water during the spring and slowly dry throughout the summer, depositing layers of evaporite minerals such as halite as they diminish.

Figure 5.2: A white ring of salt can be seen around the outer rim of this evaporating playa lake in North Dakota. Typically, these shallow lakes fill up with about a foot of water during the spring and slowly dry throughout the summer, depositing layers of evaporite minerals such as halite as they diminish.

Figure 5.3: A crystal of mirabilite.

Figure 5.3: A crystal of mirabilite.

Halite is mined in two ways. When deposited in thick beds, this salt can be excavated by mechanically carving and blasting it out. This method, called “room and pillar” mining, usually requires that pillars of salt be left at regular intervals to prevent the mine from collapsing (Figure 5.4). Another method, called solution mining, involves drilling a well into a layer of salt. In some cases, the salt exists as part of a brine that can then be pumped to the surface, where the water is then removed, leaving the salt behind. In others, fresh water is pumped down to dissolve the salt, and the solution is brought back to the surface where the salt is removed (Figure 5.5).

Figure 5.4: In pillar and room mining, the mine is divided up into smaller areas called “panels.” Groups of panels are separated from one another by extra-large (barrier) pillars that are designed to prevent total mine collapse in the event of the failure of one or more regular-sized (panel) pillars.

Figure 5.4: In pillar and room mining, the mine is divided up into smaller areas called “panels.” Groups of panels are separated from one another by extra-large (barrier) pillars that are designed to prevent total mine collapse in the event of the failure of one or more regular-sized (panel) pillars.

Figure 5.5: An example of solution mining that involves the pumping of fresh water through a borehole drilled into a subterranean salt deposit.

Figure 5.5: An example of solution mining that involves the pumping of fresh water through a borehole drilled into a subterranean salt deposit.

The Great Plains region also produces numerous industrial minerals. These include sand and gravel, cement and lime, dimension stone, and leonardite, a mineral found in association with lignitic coals and used as a source of humic acid for agriculture and remediation of polluted water sources. Gravel, sand, and other construction materials are mined extensively throughout the Dakotas and Nebraska.

The gravels of the Great Plains’ streams and valleys, especially those of Montana, yield numerous gemstones. The origins of these stones, including one of Montana’s state gemstones, the Montana agate (Figure 5.6), lie in older igneous material worn down by Pleistocene glaciers and then redeposited as glacial sediments.

Figure 5.6: The Montana agate or moss agate formed after silica-laden water infiltrated cavities in a volcanic ash bed laid down by an eruption of the Yellowstone hot spot.

Figure 5.6: The Montana agate or moss agate formed after silica-laden water infiltrated cavities in a volcanic ash bed laid down by an eruption of the Yellowstone hot spot.

In addition, catlinite, a metamorphosed mudstone that is usually reddish in color and also known as “pipestone” or “pipe clay,” is found in the 1.7-billion-year-old Sioux Quartzite of southeastern South Dakota. This material has long been used by Native Americans and artists to make sacred pipes and sculptures.

See Chapter 2: Rocks to learn more about pipestone and the Sioux Quartzite.

Outcroppings of Proterozoic and Archean granites and metamorphic rocks in Wyoming’s Hartville Uplift are similar in nature to those found in the adjacent Laramie Mountains of the Southern Rockies, and are located on the divide that marks the northern end of the Denver Basin. Ores of tin (such as the simple oxide cassiterite, SnO2, Figure 5.7), iron (as hematite), copper, silver, uranium, and gold were emplaced here through hydrothermal processes during the late Cretaceous to Paleogene periods.

Figure 5.7: Bipyramidal crystals of cassiterite (SnO<sub>2</sub>, tin oxide). Each crystal in the photo is approximately 30 millimeters (1.1 inches) across.

Figure 5.7: Bipyramidal crystals of cassiterite (SnO2, tin oxide). Each crystal in the photo is approximately 30 millimeters (1.1 inches) across.

The Great Plains of Nebraska is home to the largest known deposit of the rare earth metal niobium, found near Elk Creek. Over 100 million tons of this heat-resistant element was emplaced here in a 545-million-year-old (late Precambrian) deposit of carbonatite (a type of a carbonate-rich igneous and volcanic rock), intruded into 1.8-billion-year-old metamorphic gneisses, schists, and granites. Niobium is often used in steel alloys, rocket engines, and the manufacture of superconducting materials, such as superconducting magnets for MRI scanners.

Economic deposits of uranium and vanadium are found in Paleocene and Eocene sediments of the southern Powder River Basin of Wyoming, and in the Oligocene rocks of northwest Nebraska at the Crow Butte mine. In 2013, extraction plants in Wyoming alone provided 81% of the nation’s total uranium production. The lignitic coals of North Dakota also contain significant uranium content, and economic quantities of uranium have been produced from these coals. Uranium is primarily used for nuclear power, while vanadium’s main use is in the production of specialty steel alloys.

See Chapter 7: Energy for more information on uranium and other energy resources found in the Northwest Central.

The Black Hills of South Dakota and Wyoming represent an anomaly with respect to Great Plains physiography: they share their geologic history with the ranges of the Rocky Mountain region farther west, and thus are often considered to be the easternmost outpost of the Rockies. The Black Hills are an eroded, dome-shaped uplift that formed during the Laramide Orogeny, near the end of the Cretaceous or early Paleogene. Standing roughly 900 meters (3000 feet) above the rest of the Great Plains, they contain an exposed core of Archean and Proterozoic metamorphic, granitic, and pegmatitic rocks. The Archean rocks are approximately 2.5 to 2.7 billion years old, while the Proterozoic granites are roughly 1.7 billion years old. A sequence of sedimentary rocks, covering more than 400 million years of Earth’s history, is also exposed in these hills. Numerous mineral deposits occur in the Black Hills, the exploration and development of which led to the area’s settlement. In 1874, General George Armstrong Custer’s expedition discovered placer gold in Black Hills streams, just two years before the Battle of the Little Bighorn. Minerals containing gold, silver, molybdenum, tin, iron, copper, lead, uranium, vanadium, and rare earth elements are found in rocks ranging from Proterozoic through Quaternary in age.

Much of the gold produced in the Black Hills came from the Homestake Mine in Lead (pronounced “leed”), South Dakota, where it is found in late Cretaceous to Cenozoic veins that were intruded into early Proterozoic rocks during the Laramide Orogeny. Homestake was originally an underground mine that reached a depth of over 2400 meters (8000 feet), and it was once ranked as the deepest mine in the Western Hemisphere. Considered a “world-class” gold deposit, the mine was discovered in 1876 and sold in 1877 for the 2014 equivalent of $1.5 million dollars. It was later developed as an open pit operation (Figure 5.8). Before its eventual closure in 2002, the Homestake Mine produced over 1.1 billion grams (40 million ounces) of gold—worth over $50 billion in today’s gold prices! Outside of the Homestake area, a number of Paleocene and Eocene-aged igneous intrusions occur in the northern Black Hills. These also carry gold, sometimes in commercial quantities.

Figure 5.8: Gold veins are visible in the Homestake Mine open pit, Lead, South Dakota.

Figure 5.8: Gold veins are visible in the Homestake Mine open pit, Lead, South Dakota.

On the northwestern edge of the Black Hills, deposits of thorium, a radioactive rare earth element, have been found in the Bear Lodge Mountains near the town of Sundance, Wyoming. These Eocene-aged deposits are intruded into Paleozoic and Mesozoic sedimentary rocks. Thorium is considered to be a “critical” rare earth element, meaning one in limited supply. It has potential applications in next-generation nuclear reactors that could be safer and more environmentally friendly than current uranium reactors.

The Black Hills are also well known for deposits of beryllium, lithium, tin, tungsten, and potassium-bearing minerals. These minerals are found in early Proterozoic pegmatites, some of which contain giant crystals of spodumene (lithium aluminum inosilicate, Figure 5.9). Lithium is important to the manufacture of modern batteries, especially those used in computers, cell phones, and electric and hybrid vehicles.

Figure 5.9: Giant spodumene crystals in the pit wall of Etta Mine, Keystone, South Dakota, in 1916. Note miner (right) for scale.

Figure 5.9: Giant spodumene crystals in the pit wall of Etta Mine, Keystone, South Dakota, in 1916. Note miner (right) for scale.