Chapter 9: How Rock Bends, Buckles, and Breaks

1. Chapter 9: How Rock Bends, Buckles, and Breaks

2. How Is Rock Deformed? • Tectonics forces continuously squeeze, stretch, bend, and break rock in the lithosphere. • The source of energy is the Earth’s heat, which is transformed into to mechanical energy.

3. Stress 應力 • Definition: the force acted on per unit of surface area, SI unit = Newton/m2=Pascal. • Uniform stress is a condition in which the stress is equal in all directions. • It is confining stressor confining pressure (圍壓) applied to rocksbecause any body of rock in the lithosphere is confined by the rock around it. • Differential stress is stress that is not equal in all directions.

4. Differential (Deviatoric) Stress • The three kinds of differential stress are: • Tensional stress (張應力), which stretches rocks. • Compressional stress(壓應力), which squeezes them. • Shear stress (剪應力), which causes slippage (滑移)and translation (位移).

5. Stages of Deformation (變形) • Strain (應變)describes the deformation of a rock. • When a rock is subjected to increasing stress, it passes through three stages of deformation in succession: • Elastic deformation(彈性變形)is a reversible change in the volume or shape of a stressed rock.. • Ductile deformation(塑性變形)is an irreversible change in shape and/or volume of a rock that has been stressed beyond the elastic limit (彈性限度). • Fracture (破裂)occurs in a solid when the limits of both elastic and ductile deformation are exceeded.

6. Strain (應變) • Normal Strain (正應變) • Shear Strain (剪應變) (1) Tensional strain (2) Compressional strain

7. Figure 9.2

8. Figure 9.3

9. Ductile Deformation Versus Fracture • A brittle (脆性) substance tends to deform by fracture. • A ductile substance deforms by a change of shape. • The higher the temperature, the more ductile and less brittle a solid becomes. • Rocks are brittle at the Earth’s surface, but at depth, where temperatures are high because of the geothermal gradient, rocks become ductile.

10. A and B have the same elastic deformation, but B experiences larger ductile deformation because the temperature of A is lower than that of B or the confining pressure applied to B is higher than that to B. Figure 9.4

11. Confining Stress • Confining stress is a uniform squeezing of rock owing to the weight of all of the overlying strata. • High confining stress hinders the formation of fractures and so reduces brittle properties. • Reduction of brittleness by high confining stress is a second reason why solid rock can be bent and folded by ductile deformation.

12. Fracture • All the constituent atoms of a solid transmit stress applied to a solid. • If the stress exceeds the strength of the bond between atoms: • Either the atoms move to another place in the crystal lattice in order to relieve the stress, or; • The bonds must break, and fracture occurs.

13. Strain Rate (應變速率) • The term used for time-dependent deformation of a rock is strain rate. • Strain rate is the rate at which a rock is forced to change its shape or volume. • Strain rates in the Earth are about 10-14 to 10-15/s. • The lower the strain rate, the greater the tendency for ductile deformation to occur.

14. A has a high elastic limit and a low ductile deformation, so the temperature is low and the strain rate is also low. B has a lower elastic limit, and high temperature, so the ductile deformation is still high even B has a high strain rate. C has the lowest elastic limit and largest ductile deformation because its temperature is high and strain rate is low. Figure 9.6

15. Enhancing Ductility • High temperatures, high confining stress, and low strain rates (characteristic of the deeper crust and mantle): • Reduce brittle properties. • Enhance the ductile properties of rock.

16. Composition Affects Ductility (1) • The composition of a rock has pronounced effects on its properties. • Quartz (石英), garnet (柘榴石), and olivine (橄欖石) are very brittle. • Mica (雲母), clay (黏土), calcite (方解石), and gypsum (石膏) are ductile. • The presence of waterin a rock reduces brittleness and enhances ductile properties. • Water affects properties by weakening the chemical bonds in minerals and by forming films around minerals grains.

17. Composition Affects Ductility (2) • Rocks that readily deform by ductile deformation are limestone (石灰岩), marble (大理石), shale (頁岩), phyllite (千枚岩) and schist (片岩 ). • Rocks that tend to be brittle rather than ductile are sandstone (砂岩) and quartzite (石英岩), granite (花崗岩), granodiorite (花崗閃長岩) , and gneiss (片麻岩).

18. Rock Strength (1) • Rock strength (岩石強度) in the Earth does not change uniformly with depth. • There are two peaks in the plot of rock strength with depth. • Strength is determined by composition, temperature, and pressure. • Rocks in the crust are quartz-rich, so the strength properties of quartz play an important role in the strength properties of the crust. • Rock strength increases down to a depth about 15 km. Above 15 km rocks are strong (they fracture and fail by brittle deformation).

19. Rock Strength (2) • Below 15 km, fractures become less common because quartz weakens and rocks become increasingly ductile. • Rocks in the mantle are olivine-rich. Olivine is stronger than quartz, and the brittle-ductile transition of olivine-rich rock is reached only at a depth about 40 km.

20. Figure 9.7

21. Rock Strength (3) • By about 1300oC, rock strength is very low. • Brittle deformation is no longer possible. The disappearance of all brittle deformation properties marks the lithosphere-asthenosphere boundary. • In the crust large movements happens so slowly (low strain rates) that they can be measured only over a hundred or more years.

22. Abrupt Movement • Abrupt movement results from the fracture of brittle rocks and movement along the fractures. • Stress builds up slowly until friction between the two sides of the fault is overcome, when abrupt slippage occurs. • The largest abrupt vertical displacement ever observed occurred in 1899 at Yakutat Bay, Alaska, during an earthquake. A stretch of the Alaskan shore lifted as much as 15 m above the sea level. • Abrupt movements in the lithosphere are commonly accompanied by earthquakes.

23. Gradual Movement • Gradual movement is the slow rising, sinking, or horizontal displacement of land masses. • Tectonic movement is gradual. • Movement along faults is usually, but not always, abrupt.

24. 台灣板塊構造圖

25. 台灣的地震分布和地體構造 資料:中研院地球所

26. 從全球衛星測量系統(GPS)看臺灣地殻的變動

27. 台灣地區全球衛星測量(GPS)觀測 (水平分量)

29. Figure 9.9

30. Evidence Of Former Deformation • Structural geology is the study of rock deformation. • The law of original horizontality tells us that sedimentary strata and lava flows were initially horizontal. • If such rocks are tilted, we can conclude that deformation has occurred.

31. Dip (面的傾角) and Strike (走向) • The dip is the angle in degrees between a horizontal plane and the inclined plane, measured down from horizontal. • The strike is the compass direction (North) of the horizontal line formed by the intersection of a horizontal plane and an inclined plane.

32. Figure 9.10

33. Figure 9.11

34. Deformation By Fracture • Rock in the crust tends to be brittle and to be cut by innumerable fractures called either joints (解理 )or faults (斷層). • Most faults are inclined. • To describe the inclination, geologists have adopted two old mining terms: • The hanging-wall (上磐) block is the block of rock above an inclined fault. • The block of rock below an inclined fault is the footwall (下磐) block. • These terms, of course, do not apply to vertical faults.

35. Figure 9.12

36. Classification of Faults (1) • Faults are classified according to: • The dip of the fault. • The direction of relative movement. • Normal faults(正斷層)are caused by tensional stresses that tend to pull the crust apart, as well as by stresses created by a push from below that tend to stretch the crust. The hanging-wall block moves down relative to the footwall block.

37. Figure 9.13

38. Figure 9.13B

39. Classification of Faults (2) • A down-dropped block is a graben (地塹), or a rift (張裂), if it is bounded by two normal faults. • It is a half-graben (半地塹) if subsidence occurs along a single fault. • An upthrust block is a horst (地壘). • The world’s most famous system of grabens and half-grabens is the African Rift Valley of East Africa. • The north-south valley of the Rio Grande in New Mexico is a graben. • The valley in which the Rhine River flows through western Europe follows a series of grabens. • The Basin and Range Province in Utah, Nevada, and Idaho is a series of nearly parallel north-south striking normal faults which has formed horsts and half-grabens. The horsts are now mountain ranges and the grabens and half-grabens are sedimentary basins.

40. Figure 9.14

43. Classification of Faults (3) • Reverse faults(反斷層)arise from compressional stresses. Movement on a reverse fault is such that a hanging-wall block moves up relative to a footwall block. • Reverse fault movement shortens and thickens the crust.

44. Classification of Faults (4) • Thrust faults (逆斷層) are low-angle reverse faults with dip less than 15o. • Such faults are common in great mountain chains. • Strike-slip (走向斷層) faults are those in which the principal movement is horizontal and therefore parallel to the strike of the fault. • Strike-slip faults arise from shear stresses. • The San Andreas is a right-lateral strike-slip fault. • Apparently, movement (more than 600 km) has been occurring along it for at least 65 million years.

45. Figure 9.17

46. Figure 9.18

47. Classification of Faults (5) • Where one plate margin terminates another commences, their junction point is called a transform. • J. T. Wilson proposed that the special class of strike-slip faults that forms plate boundaries be called transform-faults(轉型斷層).

48. Figure 9.19

49. Evidence of Movement Along Faults • Movement of one mass of rock past another can cause the fault’s surfaces to be smoothed, striated (條紋細溝狀)and grooved (溝槽狀). • Striated or highly polished surfaces on hard rocks, abraded (磨損侵蝕) by movement along a fault, are called slickensides(擦痕面). • In many instances, fault movement crushes (壓碎) rock adjacent to the fault into a mass of irregular pieces, forming fault breccia (角礫岩).

50. Deformation by Bending • The bending of rock is referred to as folding (褶皺). • Monocline (單斜): the simplest fold (褶皺). The layers of rock are tilted in one direction. • Anticline (背斜): an upfold in the form of an arch. • Syncline (向斜): a downfold with a trough-like form. • Anticlines and synclines are usually paired.