59.3: Deformation - folding

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Page ID: 22856

Callan Bentley, Karen Layou, Russ Kohrs, Shelley Jaye, Matt Affolter, and Brian Ricketts
OpenGeology

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Tectonic compressional stress is the dominant force in mountain building. As plates collide, compressional stress will cause the crust to buckle and warp to produce folds. A compressional fold belt can be found in all mountain ranges around the world which have been caused by tectonic plate collision. View the Google Earth image below of the Ridge and Valley region in the Appalachian Mountains of Pennsylvania. The rock in this region includes mostly ductile sedimentary rock layers which were folded during the collision of Africa with North America as the Pangean supercontinent was being pieced together. We’re viewing this section of the Appalachians from an altitude of about 200 km. The folding pattern displayed is quite a spectacular feature seen from space.

Figure \(\PageIndex{1}\): Google Earth Image of the Appalachian Mountain fold belt in western Pennsylvania at 200 km eye altitude.

Fold Classification

Folds are classified based on their geometry and fall into 3 general categories: monoclines, anticlines and synclines.

Anticlines and Synclines

Anticlines (upfolds) and synclines (downfolds) are very common geologic structures that form in pairs in response to compression. Anticlines and synclines will share a limb of the fold. Click on the starred placemarks in the gigapixel image from eastern West Virginia, below, to learn more about specific characteristics of anticlines and synclines.

Monoclines

Monoclines (see image below) are not as common and usually form as an adjustment in the surface layers to some type of tectonic activity happening deep within the Earth’s surface. An example of this would be an uplift of a block of deeply buried “basement” rock of the continental crust.

West Bighorn monocline in the Bighorn Range, Wyoming. By Callan Bentley. — Figure \(\PageIndex{3}\): West Bighorn monocline in the Bighorn Range, Wyoming. (By Callan Bentley.)

Overturned and recumbent folds

The stress of tectonic compression is commonly applied more forcefully in one direction as one tectonic plate collides with another. The directionally applied stress may result in folding that appears to be “pushed” from one direction. When this happens, folds may begin to turn over on themselves. A fold will become increasingly asymmetric as the axial plane tips toward 90\(^{\circ}\) from vertical at which time it will be classified as recumbent.

Directionally applied stress will result in folds becoming more asymmetrical as the axial plane dips away from the vertical. Modified after unknown source. — Figure \(\PageIndex{4}\): Directionally applied stress will result in folds becoming more asymmetrical as the axial plane dips away from the vertical. (Modified after unknown source.)

Overturned Fold

Asymmetric anticline-syncline pair in marble and quartzite. By: Marli Miller Photography. — Figure \(\PageIndex{5}\): Overturned anticline-syncline pair in marble and quartzite. (By: Marli Miller Photography.)

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Overturned Fold

Recumbent Fold