Lab 7 Exercises
Part I: Relative Dating of Geological Units
Figure A represents two road cuts, or cliff faces, exposed along a road way. You can see that at first glance, the road cuts look almost identical as they both expose the same four types of rock: granite, sandstone, limestone, and shale.
1. As a quick review from Labs 4, 5, and 6, how did each of these rocks form? Briefly summarize the origin of each rock in the table below.
| Rock Type | Granite | Sandstone | Limestone | Shale |
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2. Examine the two road cuts carefully, and using the principles of stratigraphy, write a point-form geologic history for each road cut. A geologic history is a written sequence of events that describes what geological processes happened in the past to produce the stratigraphy in a given area, like a timeline. Your geologic history should use proper terms to describe each event. For example, we would say that a sedimentary rock was deposited and then lithified. We would not say that a sedimentary rock “intruded” or “erupted” because these terms are reserved for intrusive and extrusive igneous rocks, respectively. If there are any unconformities present, identify which type (review Figure 7.2.5) and briefly describe what the unconformity represents. This might include: a period of uplift and erosion, a period of non-deposition, or both.
| Youngest Event | Road Cut A (left) | Road Cut B (right) |
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3. Do the two road cuts share the same geologic history? Why or why not?
4. Which key principle of stratigraphy helped you determine the difference between the two road cuts?
Road cuts and naturally-occurring cliffs provide us with a view into the subsurface to help us understand the nature of the layers of rock beneath our feet. Another way to visualize the subsurface is using a block diagram, or block model (Figure B). The top of the diagram shows the plan view, or map view, of the Earth’s surface. The sides of the diagram show two different cross-sectional views down into the subsurface. These vertical cross-sections illustrate the geology below the surface.
We can see in Figure B, for example, that at the surface there is an active volcano (venting steam) that is connected at depth to a shallow magma chamber (E). The letters shown in this diagram, and in all the figures in this lab, are randomly assigned. In Figure B, layers G, H, J, and K are all sedimentary. Units B, C, D, E, L, and M are igneous.
5. Write a point-form geologic history for Figure B in the table below. Specify which stratigraphic principle(s) you used to justify the position of each event in the timeline.
| Youngest Event | Geologic History of Figure B | Justification (which principle of stratigraphy did you use?) |
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6. Write a point-form geologic history for Figure C in the table below. Specify which stratigraphic principle(s) you used to justify the position of each event in the timeline. If there are any unconformities present, identify which type and briefly describe what the unconformity represents. This might include: a period of uplift and erosion, a period of non-deposition, or both. All the units in Figure C are sedimentary rocks, except B which represents an erosional surface.
| Youngest Event | Geologic History of Figure C | Justification |
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7. In the space below, write a short paragraph (<150 words) describing the geologic history for Figure D using complete sentences. To describe the sequence of sedimentary rocks, you may want to use the term “overlain”, as in “the Pennsylvanian conglomerate is overlain by the Permian shale”, or as an adjective, “the overlying Permian shale”. Unit D is a basalt dyke (a type of igneous intrusion), and the line labeled as F is a fault.
8. Write a point-form geologic history for Figure E in the table below. Specify which stratigraphic principle(s) you used to justify the position of each event in the timeline. Unit J is a granite pluton and sill (two types of igneous intrusion), and the line labeled as F is a fault.
| Youngest Event | Geologic History of Figure E | Justification |
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9. Write a point-form geologic history for Figure F in the table below. Specify which stratigraphic principle(s) you used to justify the position of each event in the timeline. If there are any unconformities present, identify which type and briefly describe what the unconformity represents. Unit L represents a rhyolite dome formed by felsic lava. Letter A refers to the surface denoted by the red line. Letter F represents a fault plane. All other letters refer to sedimentary rocks. Note that units B, C, and D have been folded into anticlines and synclines.
| Youngest Event | Geologic History of Figure F | Justification |
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Part II: Characterizing Stratigraphic Relationships using a Graphic Log
For this part of the lab exercise, you will need to take samples R151, R161, R162, and R181 out of your rock kits. You will have the opportunity to thoroughly characterize each of these samples, and construct a graphic log of a succession that includes these samples.
10. Describe each of the four samples as thoroughly as possible. Items to mention in your description may include: grain size of framework grains in mm (if applicable), grain size of matrix in mm (if it can be seen), mineralogy of framework grains, mineralogy of matrix grains (if they can be seen), colour, and any other noteworthy observations (i.e., reaction with HCl). Use the space below for your answer.
11. Before a graphic log can be produced, the chronometric ages of the samples need to be constrained. When these samples were dated by a geochronologist, the following dates were returned:
- Sample R151: 138 Ma
- Sample R161: 132 Ma
- Sample R162: 388 Ma
- Sample R181: 151 Ma
Based on the information above, when (i.e., era, period) did each of the samples form? List your answers below.
- Sample R151:
- Sample R161:
- Sample R162:
- Sample R181:
12. A geoscientist has just returned from the field with some key information about the true thicknesses of the units that each of the samples were collected from. The thicknesses of each of the units are listed below:
- Sample R151: 50 m
- Sample R161: 80 m
- Sample R162: 60 m
- Sample R181: 120 m
Using all of the data that you have (i.e., sample dates, unit thicknesses), construct a simple graphic log of the stratigraphic succession on a spare letter-sized piece of paper. To do this, you will need to come up with a vertical and horizontal scale that is appropriate for the piece of paper that you are using. Use Figure 7.3.1 as a guide for your graphic log (make sure to use a ruler!).
13. Do you think that any of the surfaces between the units in your log might represent an unconformity? If so, what kind of unconformity do you think it is? If not, why?
14. Why might a geoscientist use a graphic log to characterize a stratigraphic succession?
