Additional Resources

Additional Resources

Additional Resources
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Chapter Overview

In previous chapters we have discussed how rock at the surface of the Earth is affected by the atmosphere, hydrosphere, and biosphere. We now shift our focus to processes in the solid Earth system or geosphere. In this chapter, we explain how rocks respond to these tectonic forces and how geologists study the resulting geologic structures, or architecture of Earth's crust.

The main purpose of this chapter is to help you recognize certain geologic structures, understand the forces that caused them, and thus determine the geologic history of an area.

Some principles discussed in chapter 8 should help you interpret the way structures develop in an area and their sequence of development. Recognition of unconformities as well as the principles of original horizontality, superposition, and cross-cutting relationships are as important to structural geology as they are to determining relative time.

Subsequent chapters will require an understanding and knowledge of structural geology as presented in this chapter. To understand earthquakes, for instance, one must know about faults. Appreciating how major mountain belts and the continents have evolved (chapter 20) calls for a comprehension of faulting and folding. Understanding plate tectonic theory as a whole (chapter 19) also requires a knowledge of structural geology. (Plate tectonic theory developed primarily to explain certain structural features.) In areas of active tectonics, the location of geologic structures is important in the selection of safe sites for schools, hospitals, dams, bridges, and nuclear power facilities.

Also, understanding structural geology can help us more fully appreciate the problem of finding more of Earth's dwindling natural resources. Chapter 21 discusses the association of certain geologic structures with petroleum deposits and other valuable resources.

Learning Objectives

1. Tectonic forces move and deform parts of the earth's crust. Stress is force applied to an object, while strain is a change in size and shape or both, while an object is undergoing stress. Compressional stress produces shortening strain, tensional stress produces stretching or extensional strain, and shear stress produces shear strain: parallel movement in opposite directions.
2. A body responding with elastic strain recovers its original shape. A body responding with plastic strain does not return to its original shape, while brittle strain produces fractures. Sedimentary rocks at the earth's surface are brittle.
3. A geologic map depicts rock types and structures, and a cross section is a vertical representation of a portion of the earth. Strike is the compass direction of the line formed by the intersection of an inclined bedding plane with a horizontal plane. Dip is the angle formed by the bed and a horizontal plane, and it is always measured perpendicular to strike. Strike and dip are measured in the field with a Brunton pocket transit. Horizontal and vertical beds have special symbols.

4. Folds are bends in layered rock produced by plastic strain. The axial plane (visualized as connecting the hinge lines formed by the bending of each bed in the fold) divides the fold into limbs. An anticline is an arch in which the beds dip away from the hinge line, while a syncline is a trough in which the beds dip toward the hinge line. Anticlines have their oldest beds exposed along the hinge line, while synclines have their youngest beds exposed along their hinge line.
5. Plunging folds have hinge lines that dip and produce V-shaped patterns of exposed strata.
6. Structural domes (doubly plunging anticlines) have beds that dip away from a central point, while structural basins (doubly plunging synclines) have beds that dip toward a central point.
7. Open folds have limbs with gentle dips; Isoclinal folds have limbs parallel to one another. Overturned folds have limbs that dip in the same direction. Recumbent folds have limbs that are essentially horizontal.
8. Brittle strain produces fractures in rocks called joints, if no displacement occurs. Columnar jointing and sheet jointing were mentioned in earlier chapters. Compression produces multiple joint sets.
9. Faults are fractures along which displacement occurs. The fault surface or plane separates the two sides of the fault into a hanging wall (above the fault plane) and a footwall (below the fault plane).
10. Dip-slip faults exhibit movement parallel to the dip of the fault plane. Normal faults have a hanging wall that moved down in response to tensional stress. Blocks bounded by normal faults produce grabens and rifts, if dropped down, or horsts, if raised up. Reverse faults are dip-slip faults that have a hanging wall that moved up in response to compressional stress. A thrust fault is a reverse fault with a low angle fault plane. Strike-slip faults are associated with shearing and have no vertical displacement. Left-lateral and right-lateral movement is determined by looking at displacement across the fault plane.

Related Readings

Davis, G. H., and S. J. Reynolds. 1996. Structural Geology of Rocks and Regions. 2d ed. New York: John Wiley and Sons.

Hatcher, R. D. 1995. Structural Geology - Principles, Concepts, and Problems. 2d ed. Englewood Cliff, NJ: Prentice-Hall.

Keller, E. A., and N. Pinter. 1996. Active Tectonics: Earthquakes, Uplift, and Landscapes. Upper Saddle River, NJ: Prentice-Hall.

Lisle, R. J. 1988. Geological Structures and Maps: A Practical Guide. New York: Pergamon.

Marshak, S., and G. Mitra. 1988. Basic Methods of Structural Geology. Englewood Cliffs, NJ: Prentice-Hall.

McClay, K. 1987. The Mapping of Geologic Structures. Geological Society of London Handbook. Open University Press.

Roberts, J. L. 1982. Introduction to Geologic Maps and Structures. Oxford: Pergamon Press.

Rowland, S. M., and E. M. Duebendorfer. 1994. Structural Analysis and Synthesis. 2d ed. Boston: Blackwell Scientific Publications.

Suppe, J. 1985. Principles of Structural Geology. Englewood Cliffs, NJ: Prentice-Hall.

Twiss, R. J., and E. M. Moores. 1992. Structural Geology. New York: W. H. Freeman.

Van der Pluijm, B. A., and S. Marshak. 1997. Earth Structure. Dubuque, IA: WCB/McGraw-Hill.

Answers to EOC Questions

Following are answers to the End of Chapter Questions for Chapter 15:

9.D, 10.A, 11.A, 12.C, 13.C, 14.C, 15.E, 16.B, 17.B, 18.B 19.B

Boxed Readings

This chapter contains the following boxed readings:

In Greater Depth
Box 15.1: Structures Associated with Salt Domes
Box 15.2: Is There Oil Beneath My Property - First Check the Geologic Structure
Box 15.3: California's Greatest Fault - The San Andreas

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