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Rock Deformation kyla rocel a. ceres ralf l. payonga
deformation of crust
Did you know that rocks experience stress? Stress causes rocks to deform, meaning the rocks change size or shape. Did you know?
Crustal deformation occurs when applied forces exceed the internal strength of rocks, physically changing their shapes. Theses forces are called stress, and the physical changes they create are called strain.
STRESS IS A FORCE ACTING ON A MATERIAL THAT PRODUCES A STRAIN
types of stress tensional Compressional SHEAR Tensional stress involves forces pulling in opposite directions, which results in strain that stretches and thins rock. Compressional stress involves forces pushing together, and compressional strain shows up as rock folding and thickening. Shear stress involves transverse forces; the strain shows up as opposing blocks or regions of material moving past each other.
Types of Stress Associated Plate Boundary type Resulting Strain Associated fault and offset types Tensional Divergent Stretching and thinning Normal Compressional Convergent Shortening and thickening Reverse Shear Transform Tearing Strike-slip table 1: Showing types of stress and resulting strain
DEFORMATION When rocks are stressed, the resulting strain can be elastic, ductile, or brittle. This change is generally called deformation
DEFORMATION Elastic deformation is strain that is reversible after a stress is released. For example, when you stretch a rubber band, it elastically returns to its original shape after you release it.
DEFORMATION Ductile deformation occurs when enough stress is applied to a material that the changes in its shape are permanent, and the material is no longer able to revert to its original shape. For example, if you bend a metal bar too far, it can be permanently bent out of shape.
The point at which elastic deformation is surpassed and strain becomes permanent is called the yield point. In the figure, yield point is where the line transitions from elastic deformation to ductile deformation (the end of the dashed line). Figure I: Deformation
figure i: deformation Different materials deform differently when stress is applied. Material “A” has relatively little deformation when undergoing large amounts of stress, before undergoing plastic deformation, and finally brittlely failing. Material “B” only elastically deforms before brittlely failing. Material “C” undergoes significant plastic deformation before finally failing brittlely.
DEFORMATION Brittle deformation is another critical point of no return, when rock integrity fails and the rock fractures under increasing stress.
Brittle materials have a small or large region of elastic behavior but only a small region of ductile behavior before they fracture. Ductile materials have a small region of elastic behavior and a large region of ductile behavior before they fracture. We can divide materials into two classes that depend on their relative behavior under stress.
How a material behaves will depend on several factors. Among them are: Temperature - At high temperature molecules and their bonds can stretch and move, thus materials will behave in more ductile manner. At low Temperature, materials are brittle. Confining Pressure - At high confining pressure materials are less likely to fracture because the pressure of the surroundings tends to hinder the formation of fractures. At low confining stress, material will be brittle and tend to fracture sooner.
Strain Rate - At high strain rates material tends to fracture. At low strain rates more time is available for individual atoms to move and therefore ductile behavior is favored. Composition - Some minerals, like quartz, olivine, and feldspars are very brittle. Others, like clay minerals, micas, and calcite are more ductile This is due to the chemical bond types that hold them together. Thus, the mineralogical composition of the rock will be a factor in determining the deformational behavior of the rock.
Brittle materials have a small or large region of elastic behavior but only a small region of ductile behavior before they fracture. Since many geologic features are planar in nature, we a way to uniquely define the orientation of a planar feature we first need to define two terms - strike and dip. evidence of past deformation
For an inclined plane, the strike is the compass direction of any horizontal line on the plane. The dip is the angle between a horizontal plane and the inclined plane, measured perpendicular to the direction of strike. evidence of past deformation
For beds with a 90 degrees dip (vertical) the short line crosses the strike line, and for beds with no dip (horizontal) a circle with a cross inside is used as shown. evidence of past deformation
fracture of brittle rocks Fractures produce irregularities by the form of cracks in rocks, it also produces planar features that imply the presence of stresses acting in the formation of the cracks. There are two types of planar fractures that commonly occur: joints and faults. Joints are usually planar features, so their orientation can be described as a strike and dip. They form from as a result of extensional stress acting on brittle rock. Faults occur when brittle rocks fracture and there is an offset along the fracture. When the offset is small, the displacement can be easily measured, but sometimes the displacement is so large that it is difficult to measure.
Types of Faults Faults can be divided into several different types depending on the direction of relative displacement. Dip Slip Faults - Dip slip faults are faults that have an inclined fault plane and along which the relative displacement or offset has occurred along the dip direction. Horsts & Grabens - Due to the tensional stress responsible for normal faults, they often occur in a series, with adjacent faults dipping in opposite directions. In such a case the down-dropped blocks form grabens and the uplifted blocks form horsts. In areas where tensional stress has recently affected the crust, the grabens may form rift valleys and the uplifted horst blocks may form linear mountain ranges. Half-Grabens - A normal fault that has a curved fault plane with the dip decreasing with depth can cause the down-dropped block to rotate. thrust fault, strike slip fault, and reverse fault,
Evidence of Movement on Faults Since movement on a fault involves rocks sliding past each other there may be left evidence of movement in the area of the fault plane. Fault Breccias-are crumbled up rocks consisting of angular fragments that were formed as a result of grinding and crushing movement along a fault. When the rock is broken into clay or silt size particles as a result of slippage on the fault, it is referred to as fault gouge. Slickensides are scratch marks that are left on the fault plane as one block moves relative to the other. Slickensides can be used to determine the direction and sense of motion on a fault. Mylonite - Along some faults rocks are sheared or drawn out by ductile deformation along the fault.
Deformation of Ductile Rocks When rocks deform in a ductile manner, instead of fracturing to form faults or joints, they may bend or fold, and the resulting structures are called folds. Folds result from compressional stresses or shear stresses acting over considerable time. Geometry of Folds - Folds are described by their form and orientation. The sides of a fold are called limbs. The limbs intersect at the tightest part of the fold, called the hinge A line connecting all points on the hinge is called the fold axis An imaginary plane that includes the fold axis and divides the fold as symmetrically as possible is called the axial plane of the fold.
types of folds Monoclines are the simplest types of folds. Monoclines occur when horizontal strata are bent upward so that the two limbs of the fold are still horizontal. Anticlines are folds where the originally horizontal strata has been folded upward, and the two limbs of the fold dip away from the hinge of the fold. Synclines are folds where the originally horizontal strata have been folded downward, and the two limbs of the fold dip inward toward the hinge of the fold. Synclines and anticlines usually occur together such that the limb of a syncline is also the limb of an anticline. In the diagrams above, the fold axes are horizontal, but if the fold axis is not horizontal the fold is called a plunging fold and the angle that the fold axis makes with a horizontal line is called the plunge of the fold.
If the two limbs of the fold dip away from the axis with the same angle, the fold is said to be a symmetrical fold. If the limbs dip at different angles, the folds are said to be asymmetrical folds. If the compressional stresses that cause the folding are intense, the fold can close up and have limbs that are parallel to each other. Such a fold is called an isoclinal fold (iso means same, and cline means angle, so isoclinal means the limbs have the same angle). Note the isoclinal fold depicted in the diagram below is also a symmetrical fold. If the folding is so intense that the strata on one limb of the fold becomes nearly upside down, the fold is called an overturned fold. An overturned fold with an axial plane that is nearly horizontal is called a recumbant fold. A fold that has no curvature in its hinge and straight-sided limbs that form a zigzag pattern is called a chevron fold. Further classification of folds include: types of folds Domes and Basins are formed as a result of vertical crustal motion. Domes look like an overturned bowl and result from crustal upwarping. Basins look like a bowl and result from subsidence
Flexural folds form when layers slip as stratified rocks are bent. This results in the layers maintaining their thickness as they bend and slide over one another. These are generally formed due to compressional stresses acting from either side. Flow folds form when rocks are very ductile and flow like a fluid. Different parts of the fold are drawn out by this flow to different extents resulting in layers becoming thinner in some places and thicker in outer places. The flow results in shear stresses that smear out the layers. Folds can also form in relationship to faulting of other parts of the rock body. In this case the more ductile rocks bend to conform to the movement on the fault. Folds develop in two ways: how folds form
how folds form?
MOUNTAINs AND mountain building process Mountain building (orogenesis) involves: One of the most spectacular results of deformation acting within the crust of the Earth is the formation of mountain ranges. Mountains frequently occur in elongate, linear belts. They are constructed by tectonic plate interactions in a process called orogenesis. Metamorphism. Glaciation. Erosion. Sedimentation Structural deformation. Faulting. Folding. Igneous Processes.
MOUNTAINs AND mountain building process Constructive processes, like deformation, folding, faulting, igneous processes and sedimentation build mountains up; destructive processes like erosion and glaciation, tear them back down again. Mountains are born and have a finite life span. Young mountains are high, steep, and growing upward. Middle-aged mountains are cut by erosion. Old mountains are deeply eroded and often buried. Ancient orogenic belts are found in continental interiors, now far away from plate boundaries, but provide information on ancient tectonic processes. Since orogenic continental crust generally has a low density and thus is too buoyant to subduct, if it escapes erosion it is usually preserved.
The fact that marine limestones occur at the top of Mt. Everest, indicates that deformation can cause considerable vertical movement of the crust. Such vertical movement of the crust is called uplift. Uplift is caused by deformation which also involves thickening of the low density crust and, because the crust "floats" on the higher density mantle, involves another process that controls the height of mountains. uplift and isostacy
The Principle of isostasy states that there is a flotational balance between low density rocks and high density rocks. i.e. low density crustal rocks float on higher density mantle rocks. The height at which the low density rocks float is dependent on the thickness of the low density rocks. Continents stand high because they are composed of low density rocks (granitic composition). Ocean basins stand low, because they are composed of higher density basaltic and gabbroic rocks. Isostasy is best illustrated by effects of glaciation. During an ice age crustal rocks that are covered with ice are depressed by the weight of the overlying ice. When the ice melts, the areas previously covered with ice undergo uplift. uplift and isostacy
Causes of Mountain Building Convergence at convergent plate boundaries. Continental Collisions. Rifting Oceanic lithosphere subduction beneath continental lithosphere above subduction zone rise- forms volcanic moutains Compressional stresses between trench and volcanic arc-generate fold-thrust ountain belts Similar compression behind arc that creates fold-thrust belt- results to formation of mountains Plate tectonics can cause continental crustal blocks to collide. When this occurs the rocks between the two continental blocks become folded and faulted under compressional stresses and are pushed upward to form fold-thrust mountains Continental Rifting occurs where continental crust is undergoing extensional deformation. This results in thinning of the lithosphere and upwelling of the asthenosphere which results in uplift.
References 9 Crustal deformation- An introduction to geology. (n.d.) Retrieved from https://opengeology.org/textbook/9-crustal-deformation-and-earthquakes/ Nelson, S. (2015). Tulane University. Retrieved from https://www2.tulane.edu/~sanelson/eens1110/deform.htm? fbclid=IwAR3LcE3lO_SrRwyeZ8XuwN3Gx9E9zrzPIwGf4MaDnLOEzsRN2fgQgc-iNNA

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Rock Deformation.pdf

  • 1. Rock Deformation kyla rocel a. ceres ralf l. payonga
  • 3. Did you know that rocks experience stress? Stress causes rocks to deform, meaning the rocks change size or shape. Did you know?
  • 4. Crustal deformation occurs when applied forces exceed the internal strength of rocks, physically changing their shapes. Theses forces are called stress, and the physical changes they create are called strain.
  • 5. STRESS IS A FORCE ACTING ON A MATERIAL THAT PRODUCES A STRAIN
  • 6. types of stress tensional Compressional SHEAR Tensional stress involves forces pulling in opposite directions, which results in strain that stretches and thins rock. Compressional stress involves forces pushing together, and compressional strain shows up as rock folding and thickening. Shear stress involves transverse forces; the strain shows up as opposing blocks or regions of material moving past each other.
  • 7.
  • 8. Types of Stress Associated Plate Boundary type Resulting Strain Associated fault and offset types Tensional Divergent Stretching and thinning Normal Compressional Convergent Shortening and thickening Reverse Shear Transform Tearing Strike-slip table 1: Showing types of stress and resulting strain
  • 9. DEFORMATION When rocks are stressed, the resulting strain can be elastic, ductile, or brittle. This change is generally called deformation
  • 10. DEFORMATION Elastic deformation is strain that is reversible after a stress is released. For example, when you stretch a rubber band, it elastically returns to its original shape after you release it.
  • 11. DEFORMATION Ductile deformation occurs when enough stress is applied to a material that the changes in its shape are permanent, and the material is no longer able to revert to its original shape. For example, if you bend a metal bar too far, it can be permanently bent out of shape.
  • 12. The point at which elastic deformation is surpassed and strain becomes permanent is called the yield point. In the figure, yield point is where the line transitions from elastic deformation to ductile deformation (the end of the dashed line). Figure I: Deformation
  • 13. figure i: deformation Different materials deform differently when stress is applied. Material “A” has relatively little deformation when undergoing large amounts of stress, before undergoing plastic deformation, and finally brittlely failing. Material “B” only elastically deforms before brittlely failing. Material “C” undergoes significant plastic deformation before finally failing brittlely.
  • 14. DEFORMATION Brittle deformation is another critical point of no return, when rock integrity fails and the rock fractures under increasing stress.
  • 15. Brittle materials have a small or large region of elastic behavior but only a small region of ductile behavior before they fracture. Ductile materials have a small region of elastic behavior and a large region of ductile behavior before they fracture. We can divide materials into two classes that depend on their relative behavior under stress.
  • 16.
  • 17. How a material behaves will depend on several factors. Among them are: Temperature - At high temperature molecules and their bonds can stretch and move, thus materials will behave in more ductile manner. At low Temperature, materials are brittle. Confining Pressure - At high confining pressure materials are less likely to fracture because the pressure of the surroundings tends to hinder the formation of fractures. At low confining stress, material will be brittle and tend to fracture sooner.
  • 18. Strain Rate - At high strain rates material tends to fracture. At low strain rates more time is available for individual atoms to move and therefore ductile behavior is favored. Composition - Some minerals, like quartz, olivine, and feldspars are very brittle. Others, like clay minerals, micas, and calcite are more ductile This is due to the chemical bond types that hold them together. Thus, the mineralogical composition of the rock will be a factor in determining the deformational behavior of the rock.
  • 19. Brittle materials have a small or large region of elastic behavior but only a small region of ductile behavior before they fracture. Since many geologic features are planar in nature, we a way to uniquely define the orientation of a planar feature we first need to define two terms - strike and dip. evidence of past deformation
  • 20. For an inclined plane, the strike is the compass direction of any horizontal line on the plane. The dip is the angle between a horizontal plane and the inclined plane, measured perpendicular to the direction of strike. evidence of past deformation
  • 21. For beds with a 90 degrees dip (vertical) the short line crosses the strike line, and for beds with no dip (horizontal) a circle with a cross inside is used as shown. evidence of past deformation
  • 22. fracture of brittle rocks Fractures produce irregularities by the form of cracks in rocks, it also produces planar features that imply the presence of stresses acting in the formation of the cracks. There are two types of planar fractures that commonly occur: joints and faults. Joints are usually planar features, so their orientation can be described as a strike and dip. They form from as a result of extensional stress acting on brittle rock. Faults occur when brittle rocks fracture and there is an offset along the fracture. When the offset is small, the displacement can be easily measured, but sometimes the displacement is so large that it is difficult to measure.
  • 23. Types of Faults Faults can be divided into several different types depending on the direction of relative displacement. Dip Slip Faults - Dip slip faults are faults that have an inclined fault plane and along which the relative displacement or offset has occurred along the dip direction. Horsts & Grabens - Due to the tensional stress responsible for normal faults, they often occur in a series, with adjacent faults dipping in opposite directions. In such a case the down-dropped blocks form grabens and the uplifted blocks form horsts. In areas where tensional stress has recently affected the crust, the grabens may form rift valleys and the uplifted horst blocks may form linear mountain ranges. Half-Grabens - A normal fault that has a curved fault plane with the dip decreasing with depth can cause the down-dropped block to rotate. thrust fault, strike slip fault, and reverse fault,
  • 24. Evidence of Movement on Faults Since movement on a fault involves rocks sliding past each other there may be left evidence of movement in the area of the fault plane. Fault Breccias-are crumbled up rocks consisting of angular fragments that were formed as a result of grinding and crushing movement along a fault. When the rock is broken into clay or silt size particles as a result of slippage on the fault, it is referred to as fault gouge. Slickensides are scratch marks that are left on the fault plane as one block moves relative to the other. Slickensides can be used to determine the direction and sense of motion on a fault. Mylonite - Along some faults rocks are sheared or drawn out by ductile deformation along the fault.
  • 25. Deformation of Ductile Rocks When rocks deform in a ductile manner, instead of fracturing to form faults or joints, they may bend or fold, and the resulting structures are called folds. Folds result from compressional stresses or shear stresses acting over considerable time. Geometry of Folds - Folds are described by their form and orientation. The sides of a fold are called limbs. The limbs intersect at the tightest part of the fold, called the hinge A line connecting all points on the hinge is called the fold axis An imaginary plane that includes the fold axis and divides the fold as symmetrically as possible is called the axial plane of the fold.
  • 26. types of folds Monoclines are the simplest types of folds. Monoclines occur when horizontal strata are bent upward so that the two limbs of the fold are still horizontal. Anticlines are folds where the originally horizontal strata has been folded upward, and the two limbs of the fold dip away from the hinge of the fold. Synclines are folds where the originally horizontal strata have been folded downward, and the two limbs of the fold dip inward toward the hinge of the fold. Synclines and anticlines usually occur together such that the limb of a syncline is also the limb of an anticline. In the diagrams above, the fold axes are horizontal, but if the fold axis is not horizontal the fold is called a plunging fold and the angle that the fold axis makes with a horizontal line is called the plunge of the fold.
  • 27. If the two limbs of the fold dip away from the axis with the same angle, the fold is said to be a symmetrical fold. If the limbs dip at different angles, the folds are said to be asymmetrical folds. If the compressional stresses that cause the folding are intense, the fold can close up and have limbs that are parallel to each other. Such a fold is called an isoclinal fold (iso means same, and cline means angle, so isoclinal means the limbs have the same angle). Note the isoclinal fold depicted in the diagram below is also a symmetrical fold. If the folding is so intense that the strata on one limb of the fold becomes nearly upside down, the fold is called an overturned fold. An overturned fold with an axial plane that is nearly horizontal is called a recumbant fold. A fold that has no curvature in its hinge and straight-sided limbs that form a zigzag pattern is called a chevron fold. Further classification of folds include: types of folds Domes and Basins are formed as a result of vertical crustal motion. Domes look like an overturned bowl and result from crustal upwarping. Basins look like a bowl and result from subsidence
  • 28. Flexural folds form when layers slip as stratified rocks are bent. This results in the layers maintaining their thickness as they bend and slide over one another. These are generally formed due to compressional stresses acting from either side. Flow folds form when rocks are very ductile and flow like a fluid. Different parts of the fold are drawn out by this flow to different extents resulting in layers becoming thinner in some places and thicker in outer places. The flow results in shear stresses that smear out the layers. Folds can also form in relationship to faulting of other parts of the rock body. In this case the more ductile rocks bend to conform to the movement on the fault. Folds develop in two ways: how folds form
  • 30. MOUNTAINs AND mountain building process Mountain building (orogenesis) involves: One of the most spectacular results of deformation acting within the crust of the Earth is the formation of mountain ranges. Mountains frequently occur in elongate, linear belts. They are constructed by tectonic plate interactions in a process called orogenesis. Metamorphism. Glaciation. Erosion. Sedimentation Structural deformation. Faulting. Folding. Igneous Processes.
  • 31. MOUNTAINs AND mountain building process Constructive processes, like deformation, folding, faulting, igneous processes and sedimentation build mountains up; destructive processes like erosion and glaciation, tear them back down again. Mountains are born and have a finite life span. Young mountains are high, steep, and growing upward. Middle-aged mountains are cut by erosion. Old mountains are deeply eroded and often buried. Ancient orogenic belts are found in continental interiors, now far away from plate boundaries, but provide information on ancient tectonic processes. Since orogenic continental crust generally has a low density and thus is too buoyant to subduct, if it escapes erosion it is usually preserved.
  • 32. The fact that marine limestones occur at the top of Mt. Everest, indicates that deformation can cause considerable vertical movement of the crust. Such vertical movement of the crust is called uplift. Uplift is caused by deformation which also involves thickening of the low density crust and, because the crust "floats" on the higher density mantle, involves another process that controls the height of mountains. uplift and isostacy
  • 33. The Principle of isostasy states that there is a flotational balance between low density rocks and high density rocks. i.e. low density crustal rocks float on higher density mantle rocks. The height at which the low density rocks float is dependent on the thickness of the low density rocks. Continents stand high because they are composed of low density rocks (granitic composition). Ocean basins stand low, because they are composed of higher density basaltic and gabbroic rocks. Isostasy is best illustrated by effects of glaciation. During an ice age crustal rocks that are covered with ice are depressed by the weight of the overlying ice. When the ice melts, the areas previously covered with ice undergo uplift. uplift and isostacy
  • 34. Causes of Mountain Building Convergence at convergent plate boundaries. Continental Collisions. Rifting Oceanic lithosphere subduction beneath continental lithosphere above subduction zone rise- forms volcanic moutains Compressional stresses between trench and volcanic arc-generate fold-thrust ountain belts Similar compression behind arc that creates fold-thrust belt- results to formation of mountains Plate tectonics can cause continental crustal blocks to collide. When this occurs the rocks between the two continental blocks become folded and faulted under compressional stresses and are pushed upward to form fold-thrust mountains Continental Rifting occurs where continental crust is undergoing extensional deformation. This results in thinning of the lithosphere and upwelling of the asthenosphere which results in uplift.
  • 35. References 9 Crustal deformation- An introduction to geology. (n.d.) Retrieved from https://opengeology.org/textbook/9-crustal-deformation-and-earthquakes/ Nelson, S. (2015). Tulane University. Retrieved from https://www2.tulane.edu/~sanelson/eens1110/deform.htm? fbclid=IwAR3LcE3lO_SrRwyeZ8XuwN3Gx9E9zrzPIwGf4MaDnLOEzsRN2fgQgc-iNNA