The basin consists of a large asymmetric syncline of Paleozoic, Mesozoic, and Cenozoicsedimentary rock layers, trending north to south along the east side of the Front Range from the vicinity of Pueblo northward into Wyoming. The basin is deepest near Denver, where it reaches a depth of approximately 13,000 ft (3900 m) below the surface. The basin is strongly asymmetric: the Dakota Sandstone outcrops in a "hog-back" ridge near Morrison a few miles west of Denver, reaches its maximum depth beneath Denver, then ascends very gradually to its eastern outcrop in central Kansas. The Dakota hogback exposes Dakota Sandstone overlying and protecting the Morrison Formation beneath and to the west. Between Golden and Morrison, the Dakota hogback is called Dinosaur Ridge and is the site of a dinosaurtrackway and dinosaur fossils exposed in the outcrop that are part of a Colorado State Natural Area and Geological Points of Interest. The Lyons and Lykins formations outcrop in a smaller hogback. Farther west, the Fountain Formation outcrops as flatirons and forms the namesake of the Red Rocks Park and Amphitheatre. Here, against the eastern edge of the Rocky Mountain Front range, the Fountain Formation is in nonconformable contact with the Precambrian crystalline rock of the Idaho Springs Formation.
The present basin was within the Cretaceous Interior Seaway, which deposited a thick Cretaceous section in the basin. Dinosaur fossils from the Maastrichtian have been unearthed in the Denver Basin.[1]
The basin was most likely further deepened in Paleogene time, between 66 and 45 million years ago, during the Laramide orogeny that created the modern Colorado Rockies. In particular, the uplifting of the Rockies in the Front Range caused the crust near Denver to buckle downward on the eastern side, deepening the basin. The basin later became filled with sediment eroded from the Rockies. The Front Range peaks rise approximately 22,000 ft (6600 m) from the floor of the basin under Denver.
The deep part of the basin near Denver became filled with Paleogene sandstone and conglomerate, a layer now called the Denver Formation. In the regions to the north and south of Denver, however, stream erosion removed the Paleogene layers, revealing the underlying CretaceousPierre Shale.
The great majority of Denver Basin oil and gas fields produce from Cretaceous sandstones, although the PermianLyons Sandstone is also a producer. Oil has also been produced from Permian sandstones and dolomites and Pennsylvanianlimestones in the Nebraska part of the basin.
The Denver Basin aquifer system consists of a layered sequence of four aquifers in beds of permeable conglomerate, sandstone, and siltstone. Layers of relatively impermeable shale separate the aquifers and impede the vertical movement of ground water between the aquifers. The northern part of this aquifer system underlies the surficial aquifer of the South Platte River. Although the Denver Basin aquifer system and the surficial aquifer are hydraulically connected in part of this area, they primarily function as separate aquifer systems which serve as important sources of water supply in the region.[12][13][14] Denver and its suburbs such as the communities in Douglas County draw ground water from the aquifers in the Denver Basin. There is recharge of about 40,000 acre-feet per year from the broken land to the west of the basin and withdrawals of about 10 times as much.[15] Ground water levels have dropped in the aquifers especially near population centers which draw on the aquifers for water.[16]
Cement, construction aggregate and dimension stone
Small amounts of gold have been mined from sands and gravels in the Denver area since the Pikes Peak Gold Rush of 1858. Some sand and gravel pits still recover gold in their washing operations.
A small amount of uranium ore has been mined from the Dakota Sandstone at Morrison, Colorado, where the sandstone is impregnated with petroleum.[17]Uranium is known to exist in roll-front type deposits in the Denver Basin, but the basin has never been a major source of uranium.[18]
^Peggy Williams, Shallow DJ gas, Oil and Gas Investor, Mar. 2007, p.51-54.
^Paul E. Soister (1978) Geologic setting of coal in the Denver Basin, in Energy Resources of the Denver Basin, Denver: Rocky Mountain Association of Geologists, p.153-159.
^Robert J. Wright and Donald L. Everhart (1960) Uranium, in Mineral Resources of Colorado First Sequel, Denver: Colorado Mineral Resources Board, p.363.
^Louis J. O'Connor and Bruce D. Smith (1978) Magnetic and electrical study of a roll-front uranium deposit in the Denver Basin, Colorado, in Energy Resources of the Denver Basin, Denver: Rocky Mountain Association of Geologists, p.153-159.
Roadside Geology of Colorado, Halka Chronic, Mountain Press Publishing Company, Missoula, Montana (1980).
Emmons, Samuel Franklin, 1841-1911; Cross, Whitman, 1854-1949; Eldridge, George Homans, 1854-1905, Geology of the Denver basin in Colorado (1896) Washington D.C, Government Printing Office