Folding, Faulting, and Mountains Folding – Mount Kidd, Alberta, Canada – Figure 17.2 in text GLY 2010 – Summer 2013 - Lecture 13
Stress Stress is a force that is capable of greatly deforming rocks, and may result in folding or faulting of rock, and even to the building of mountains
Types of Stress There are three types of stress Compression Tension Shear Each type is discussed on next slides
Compression Opposing forces directed inward along a single line Compression shortens an object along the axis of compression, and thickens it in the directions perpendicular to the stress direction After Before
Tension Tension is the result of divergence, pulling an object in opposite directions along a common axis Tension lengthens an object along the axis of tension, and thins it in the perpendicular directions After Before
Tensional Cracking Tension can produce cracks in the direction perpendicular to the axis of tension Cracking develops
Tension Crack Pictures Left photo: Ground failure along North Deschutes Parkway showing lateral spread toward Capitol Lake, which is to the right of the photograph; view is to the north. (N47.040° W122.915°; 03/01/2001) Source: http://peer.berkeley.edu/nisqually/geotech/liquefaction/lateralspread/dcp_0207_s.jpg Right Photo: Lateral spreading of railroad embankment extending from Marathon Park (looking northeast). (N47.03723° W122.90963°; 02/28/2001) Photo Source: http://peer.berkeley.edu/nisqually/geotech/liquefaction/lateralspread/c03.jpg Nisqually Earthquake, 2/28/01, in Washington caused tension cracking.
Shear Opposing stress is created by two plates moving in opposite directions
Responses to Stress There are three responses to stress Elastic Plastic Rupture
Elastic Substances Behave elastically, stretch without breaking Snap back to their original position, when stress is removed Elastic limit: a limit beyond which substances cannot be stretched without breaking Example: Rubber band
Plastic Substances Slow deformation without breaking Plastically deformed substances do not return to their original shape when the stress is removed Rate of deformation is important - Stress applied quickly will cause rupture Rocks subjected to stress at high confining (load) pressures, and moderate to high temperatures, may deform plastically Example: Silly putty Movie from: http://vern.com/putty/creations/george.mpg Silly George, by Vern Hart Time-lapse slumping of silly putty. Notice movement in upper left corner.
Plastic Deformation The rate of plastic deformation makes a difference Silly putty breaks if pulled rapidly, stretches if pulled slowly Movie: ddx.avi, converted from ddx.avi
Rupture Elastic substances stretched beyond the elastic limit, or plastic substances deformed quickly, will rupture Rupture is called brittle failure
Deformation Rocks subjected to stress may: Deform by folding Rupture, with subsequent movement along the plane of rupture - this is called faulting Fold, then rupture
Folding Folds may be described in terms of two parameters: Axial Plane Limbs Axial Plane Limb Limb
Anticline If the fold is convex upward, it is called an anticline
Anticlinal Fold Rainbow Gap, Virginia Photo: Henry Johnson
Atlas Mountains Anticline One of the best exposures of a complexly folded mountain belt anywhere occurs in the Atlas Mountain system of northwest Africa
Domes Domes are anticlines that curve in three dimensions, like an upside down bowl Figure shows the Black Hills, South Dakota Diagram of dome – Figure 17.6, text
Eroded Dome, Sinclair, Wyoming
Syncline If the fold is convex downward, it is called a syncline
Syncline Photo Photo: Duncan Heron Synclinal fold exposed by roadcut
Anticline-Syncline Pair Anticline-Syncline pair in Devonian Old Red Sandstone. SW Wales, UK Note the different fold shapes
Basins Basins are syncline that curve in three dimensions, like a bowl Diagram: Figure 17.7 in text
Overturned Folds Overturned fold in lower center of picture
Recumbent Folds Recumbent folds are defined as folds with horizontal (<10° dip) axial surfaces Photo: Ron Perkins http://www.geo.duke.edu/Sched/Geopages/geo41/st.htm Photo # st036th.gif
Fold Diagram Diagram shows the major types of folds Figure 17.3 in text Diagram shows the major types of folds
Plunging Folds The axes of the folds may be tilted, creating a series of plunging folds Figure 17.4 in text
Folding Animation From Chapter 17, FoldingV2_PC.ppt
Joints Three joint sets (left photo) Video: Joints_&_Dikes,_Thunder_Hole,_Acadia.wmv from author Three joint sets (left photo) Joints and dikes, Acadia National Park video (right)
(Click picture to remove block) Faults A fault is a fracture along which definite movement has occurred (Click picture to remove block)
Strike and Dip The strike is any horizontal line drawn on an inclined surface. Strike-slip faulting is the result of shear forces. The strike-dip symbol, used on geologic maps, is shown - the long direction points in the horizontal direction, and the shorter side shows dip direction
Strike-slip Direction Strike-slip faults are further described as "right-lateral" or "left-lateral" depending if the block opposite the viewer moved to the right or left, respectively
Strike Slip Fault Photo: Arthur G. Sylvester. San Jacinto fault, Anza, Southern California
Right-Lateral Strike Slip Block is displaced to the right, looking across the fault Image: Source: http://www.gps.caltech.edu/~meltzner/wallacecreek/misc/images/rightlat.gif
Strike Slip Faults Right Lateral Near Coos Bay, Oregon
Left-Lateral Strike Slip Block is displaced to the left, looking across the fault Image: Source: http://www.gps.caltech.edu/~meltzner/wallacecreek/misc/images/leftlat.gif
Strike Slip Faults - Left Lateral Near Lillooet, British Columbia
Dip-slip Faults Dip direction is always perpendicular to the strike line
Fault Terminology Foot Wall and Hanging Wall are borrowed from mining terminology Ore veins are often deposited along faults
Normal Fault Normal faulting results from tensional forces Hanging wall moves down relative to the footwall (here, to the right) Places younger rocks on top of older Image: Source: http://www.gps.caltech.edu/~meltzner/wallacecreek/misc/images/normal.gif
Sevier Normal Fault Figure 17.8 in text
Death Valley Normal Faults photo: http://www.uoregon.edu/~millerm/DVN1.html
Reverse Fault Reverse faulting results from compressional forces Hanging wall moves up relative to the footwall (here, to the left) Places older rocks on top of younger Source: http://www.gps.caltech.edu/~meltzner/wallacecreek/misc/images/reverse.gif
Reverse Fault Reverse faults and associated fold http://www.uoregon.edu/~millerm/KlamT.html Near Klamath Falls, OR. Reverse faults and associated fold
Thrust Fault Thrust faults are low angle reverse faults They sometimes move large distances (tens of kilometers) Image: Source: http://www.gps.caltech.edu/~meltzner/wallacecreek/misc/images/thrust.gif
Lewis Overthrust Photo: http://www.uoregon.edu/~millerm/Lewis1.html Lewis Thrust fault. As viewed from Marias Pass, Glacier National Park, Montana. Looking N. Green arrow points to fault. There, Precambrian rocks of the Belt Supergroup lie directly on top Cretaceous shale and sandstone.
Explanation of Lewis Overthrust Image: chfsketch.jpg Chief Mountain was moved about forty kilometers and isolated by erosion Chief Mountain is much older (Precambrian) than the rock upon which it rests (Cretaceous)
Chief Mountain Older rock above younger, typical of thrust faults Glacier National Park, Montana
Oblique Slip Image: Source: http://www.gps.caltech.edu/~meltzner/wallacecreek/misc/images/oblique.gif Oblique-slip is a combination of vertical and horizontal movement
Horst and Graben Occur when there is offset along high-angle normal faults, so that one block (the graben) drops relative to the blocks (horsts) on either side. Tensional forces create these structures
San Andreas/Garlock Faults From Space
San Andreas Fault Pacific plate, left North America, right
San Andreas Offsetting Fence
Fault Animations From Chapter 17, FaultsV2_PC.ppt
Fault Diagram Summary Figure 17.9 in text
Orogenesis Tectonic forces often create mountains, a process called orogenesis There are several types of mountains Folded Faulted Upwarped Volcanic
Orogenesis by Folding Plate collisions involving continental plates can produce high mountains Examples: Himalayas (India, Tibet, China) Alps (Europe) Urals (Europe/Asia boundary) Appalachians
High peaks in the Himalayas Himalayan Mountains Mt. Everest High peaks in the Himalayas
Owens Valley and the Sierra Nevada Range
Orogenesis by Upwarping Formed when a large region of the earth’s crust is bent into a broad, regional uplift with little apparent deformation of the rocks Upwarping may be due to local vertical motion, rather than plate tectonic forces - often far from plate boundaries
Custer State Park, Black Hills, South Dakota
Volcanic Mountains
(Click picture to restore block) Faults A fault is a fracture along which definite movement has occurred (Click picture to restore block)