Unconformity

Types

Disconformity

A disconformity is an unconformity between parallel layers of sedimentary rocks which represents a period of erosion or non-deposition. Disconformities are marked by features of subaerial erosion. This type of erosion can leave channels and paleosols in the rock record.

Nonconformity

A nonconformity exists between sedimentary rocks and metamorphic or igneous rocks when the sedimentary rock lies above and was deposited on the pre-existing and eroded metamorphic or igneous rock. Namely, if the rock below the break is igneous or has lost its bedding due to metamorphism, then the plane of juncture is a nonconformity.

Angular unconformity

An angular unconformity is an unconformity where horizontally parallel strata of sedimentary rock are deposited on tilted and eroded layers, producing an angular discordance with the overlying horizontal layers. The whole sequence may later be deformed and tilted by further orogenic activity. A typical case history is presented by the Briançonnais realm (Swiss and French Prealps) during the Jurassic.

Angular unconformities can occur in ash fall layers of pyroclastic rock deposited by volcanoes during explosive eruptions. In these cases, the hiatus in deposition represented by the unconformity may be geologically very short – hours, days or weeks.

Paraconformity

A paraconformity is a type of unconformity in which the sedimentary layers above and below the unconformity are parallel, but there is no obvious erosional break between them. A break in sedimentation is indicated, for example, by fossil evidence. It is also called nondepositional unconformity or pseudoconformity. Short paraconformities are called diastems.

Buttress unconformity

A buttress unconformity, also known as onlap unconformity, occurs when younger bedding is deposited against older strata thus influencing its bedding structure.

Blended unconformity

A blended unconformity is a type of disconformity or nonconformity with no distinct separation plane or contact, sometimes consisting of soils, paleosols, or beds of pebbles derived from the underlying rock.

Gallery

File:Disconformity Horni Pocernice.jpg|Disconformity at Horni Pocernice, Czech Republic File:Borden-Sharon unconformity.jpg|Disconformity (at the hammer) between underlying Mississippian Borden Formation and overlying Pennsylvanian Sharon Conglomerate, near Jackson, Ohio File:Taum Sauk precambrian-cambrian unconformity.jpg|There is a billion-year gap in the geologic record where this 500-million-year-old dolomite nonconformably overlies 1.5-billion-year-old rhyolite, near Taum Sauk Hydroelectric Power Station, Missouri. File:Ratssteinbruch Dresden-Doelzschen.jpg|Nonconformity at Ratssteinbruch near Dresden, Germany File:Siccar Point red capstone closeup.jpg|Hutton's angular unconformity at Siccar Point where Famennian age (371–359 Ma) Devonian Old Red Sandstone overlies Llandovery age (444–433 Ma) Silurian greywacke File:Angular Unconformity at Praia do Telheiro in Algarve in Portugal.png|Angular unconformity of Triassic rocks overlying steeply-tilted Carboniferous rocks at Praia do Telheiro, Portugal File:Steamboat Butte New Mexico.jpg|Angular unconformity between the underlying Dockum Group and the overlying Exeter Sandstone at Steamboat Butte in the valley of the Dry Cimmarron, New Mexico File:Winkeldiskordanz.JPG|Angular unconformity in Jingtai County, China File:Tephra Layers at Chimborazo Volcano in Ecuador.jpg|Angular unconformity in pyroclastic rock layers erupted by Chimborazo volcano, Ecuador Image:GP_0147_%282%29.JPG|Geological unconformity, Camelback mountain, Arizona, showing deposition of Chattian sandstone (right) on Precambrian granite (left).

References

References

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