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Which of the following statements about relative and absolute age dating is most accurate

15/12/2020 Client: saad24vbs Deadline: 7 Days

2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 1/41


Homework 5 Geologic Time Due: 11:59pm on Sunday, February 28, 2016


You will receive no credit for items you complete after the assignment is due. Grading Policy


Interactive Animation: Relative Geologic Dating


When you have finished, answer the questions.


Part A


Which of the following statements about relative and absolute age dating is most accurate?


ANSWER:


Correct


Part B


What is the principle of original horizontality?


ANSWER:


Relative age dating places rocks and events in chronological order and can provide information about absolute age.


Relative age dating provides information about absolute ages but does not place rocks and events in chronological order.


Relative age dating places rocks and events in chronological order but does not provide information about absolute age.


Relative age dating does not provide information about absolute ages, nor does it place rocks and events in chronological order.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 2/41


Correct


Part C


What is the principle of superposition?


ANSWER:


Correct


Part D


What is the principle of cross­cutting relationships?


ANSWER:


Correct


Part E


Five layers of rock are cut by two faults. Both faults cut through all five layers of rock. Fault A breaks through to the surface, whereas fault B does not. Which of the following statements about faults A and B is most accurate?


Metamorphic rocks are close to horizontal when deposited.


Sedimentary rocks are close to horizontal when deposited.


Sedimentary rocks are close to horizontal when eroded.


Metamorphic rocks are close to horizontal when eroded.


Within a sequence of rock layers formed at Earth's surface, rock layers in the middle of a sequence are older.


Within a sequence of rock layers formed at Earth's surface, rock layers higher in the sequence are older.


Within a sequence of rock layers formed at Earth's surface, rock layers lower in the sequence are older.


Geologic features that cut through rocks must form at roughly the same time as the rocks that they cut through.


Geologic features that cut through rocks must form before the rocks that they cut through.


Geologic features that cut through rocks must form after the rocks that they cut through.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 3/41


ANSWER:


Correct


Part F


Which principle of relative age dating is important for determining the relative age of igneous rock that has intruded into overlying rock?


ANSWER:


Correct


Part G


A fault (F) breaks three layers of sedimentary rock (S). An igneous intrusion (I1) has broken through the bottommost layer of rock. A second igneous intrusion (I2) has moved up the fault and pooled on top of the uppermost layer of rock. Which event would be considered the youngest?


ANSWER:


Correct


Faults A and B are about the same age, and both are older than the five layers of rock.


Fault A is younger than fault B, and both are older than the five layers of rock.


Faults A and B are about the same age, and both are younger than the five layers of rock.


Fault A is younger than fault B, and both are younger than the five layers of rock.


the principle of original horizontality


the principle of cross­cutting relationships


the principle of intrusive relationships


the principle of superposition


Faulting of rock along F is the youngest event. We know this because all three layers of sedimentary rock have been broken.


The intrusion of I2 is the youngest event. We can know this because I2 sits on top of all other rocks.


Deposition of the three sedimentary layers, S, is the youngest event. We know this because the fault underlies the igneous rocks.


The intrusion of I1 or I2 is the youngest event. Without more information, we cannot know which igneous rock is youngest.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 4/41


SmartFigure: Relative Dating


Launch the SmartFigure Video


When you have finished, answer the questions.


Part A


A sandstone contains inclusions of metamorphic rock. An igneous dike cuts both the sandstone and inclusions. List the rocks from youngest to oldest.


Hint 1.


Use your knowledge regarding the principles of cross­cutting relationships and dating by inclusions to answer this question.


ANSWER:


Correct


Part B


metamorphic rock, igneous dike, sandstone


igneous dike, sandstone, metamorphic rock


metamorphic rock, sandstone, igneous dike


sandstone, metamorphic rock, igneous dike


igneous dike, metamorphic rock, sandstone


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 5/41


If a sequence of sedimentary units is cut by a fault, what does the principle of cross­cutting relationships tell a geologist?


Hint 1.


Recall what the principle cross­cutting relationships states and how it is used for relative age dating.


ANSWER:


Correct


Part C


Which of the following describes the principle of original horizontality?


Hint 1.


The video showed a sequence of folded sedimentary rocks. What had to occur to form this feature?


ANSWER:


Correct


Part D


The sedimentary units on the left side of the fault are the same as those on the right side.


All of the sedimentary units must have been deposited and lithified before being cut by the fault.


The fault is older than the sedimentary sequence.


Sedimentary layers are laid down horizontally.


The oldest sedimentary unit is located at the base of the sequence, while the youngest is at the top.


Inclusions within a sedimentary rock are older than the sedimentary rock itself.


Folded sedimentary layers were originally laid down flat and later deformed.


A fault or dike that cut a sedimentary sequence is younger than the sedimentary rocks it breaks through.


Undeformed sedimentary layers present on one side of a river­cut canyon are the same as those on the opposite side.


The oldest sedimentary unit is located at the base of the sequence, while the youngest is at the top.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 6/41


An undeformed sequence of sedimentary rocks is exposed in a large river canyon. Which two principles would be demonstrated by the rocks?


Hint 1.


Think back to the five principles you learned about in the video. Which two would be the most applicable to an undeformed rock sequence that has been eroded by a large stream?


ANSWER:


Correct


Part E


An igneous dike cuts through limestone, but not through the overlying sandstone. Which of the following statements is most accurate?


Hint 1.


Think about how the principles of superposition and cross­cutting relationships are used for this question.


ANSWER:


Correct


principles of lateral continuity and inclusions


principles of superposition and lateral continuity


principles of cross­cutting relationships and superposition


principles of superposition and dating by inclusions


principles of lateral continuity and cross­cutting relationships


First, the sandstone was laid down, next the limestone was deposited, and finally was cut by the igneous dike.


The limestone and sandstone were deposited and then cut by the igneous dike.


First, the limestone was laid down, then intruded by the igneous dike, and lastly the sandstone was deposited.


The igneous dike represents the oldest rock, while the sedimentary rocks are relatively younger.


First, the limestone was laid down, folded and cut by an igneous dike, and finally the sandstone was deposited.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 7/41


GeoTutor: Constructing an Order of Sequence of Geologic Events ­ Geologic Time Scale


Geologists have divided the whole of history into units of increasing magnitude. This is called the geologic time scale. The entire time scale was originally based on relative dating, since radiometric dating was not available at the time. Absolute dating techniques determine a numerical age of strata given in number of years. Relative dating techniques, on the other hand, determine the age of a stratum relative to other strata (i.e., if it is younger or older), without providing any numerical data. Geologists have been able to determine the relative ages of rocks and any fossils they contain to reconstruct a history that reveals the evolution of Earth's continents and living organisms using four laws of stratigraphy:


1. Law of Superposition: Younger strata are deposited on top of older strata. 2. Law of Original Horizontality: Strata are deposited horizontally. Tilted strata had been tilted by some geologic event after the time of deposition. 3. Law of Lateral Continuity: Layers of sediment initially extend laterally in all directions. As a result, rocks that are otherwise similar, but are now separated by a valley or other erosional feature, can be assumed to be originally continuous.


4. Law of Cross­Cutting Relationships: Magma intrudes and crystallizes (forming features such as faults and dikes). These features are younger than the strata they cut through.


The geologic time scale subdivides the 4.6­billion­year history of Earth into several units, outlining the time frames of several events of the geologic past. See below for the geologic time scale chart.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 8/41


Part A ­ Laws of stratigraphy


In the figure below, a series of geologic events, A­J, shows the configuration of rocks as seen from a road. Some strata have been tilted, and a volcanic dike has intruded some


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 9/41


of the rocks. Use the laws of stratigraphy to rank these strata.


Rank the strata from oldest to youngest.


Hint 1. The Law of Cross­Cutting Relationships


The volcanic dike (H) must be older than any strata it does not cut through and younger than any strata it does cut through, because the strata it cuts through must have been there before the intrusion of magma.


Hint 2. The Law of Original Horizontality


Pretend the tilted strata are horizontal. That is, "D" is above "A," "C" is above "A," and so on. The Law of Original Horizontality states that strata are deposited horizontally in their original states. Tilted strata had been tilted by some geologic event after the time of deposition, but still retain their relative order.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 10/41


All attempts used; correct answer displayed


Notice that the tilted strata are immediately overlain by horizontal strata. This can only occur if erosion has partially removed the tilted strata so they all terminate at the same depth.


Part B ­ The geologic time scale and unconformities


Gaps in the rock record are called unconformities. Unconformities are caused by periods of erosion that have occurred between periods of deposition, which have erased a portion of the rock record. There are three types of unconformities: (1) angular unconformities occur when tilted strata are overlain by horizontal strata—Click here to see an angular unconformity; (2) disconformities occur when strata are separated by an erosional surface—Click here to see a disconformity); (3) nonconformities occur when strata overlay igneous or metamorphic rocks that are resistant to erosion—Click here to see a nonconformity.


Now use the figure below, which has labeled each of the rock strata/layers from Part A with their respective geologic time periods, to fill in the gaps in the following sentences.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 11/41


Match the words in the left column to the appropriate blanks in the sentences on the right. Make certain each sentence is complete before submitting your answer.


Hint 1. How to determine the missing time period


Identify the youngest and oldest strata in the diagram, and use the geologic time scale provided above to find all of the geologic periods between these ages.


Hint 2. The types of unconformities


The volcanic dike terminating abruptly at a stratigraphic boundary would indicate that erosion has occurred.


Hint 3. The age of unconformities


An unconformity must be at least the age of the strata overlying it and can be as old as the strata below it.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 12/41


Correct


The tilting of the Triassic rocks could have occurred in the Triassic, Jurassic, or Cretaceous periods. This amounts to an uncertainty of at least 55 million years.


Interactive Animation: Angular Uncomformities, Noncomformities, and Discomformities


When you have finished, answer the questions.


Help












1. The Quaternary and Tertiary rocks are separated by this type of unconformity:


a disconformity .


2. Due to an unconformity, the Jurassic period is missing from the rock record.


3. The Triassic rocks must have been most likely tilted during or after the Triassic period


4. The dike dates at least to the Quarternary period.


5. The Triassic and Cretaceous rocks are separated by this type of unconformity:


an angular unconformity .


Reset


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 13/41


Part A


Which image is an example of an angular unconformity?


SEE IMAGES BELOW FOR ANSWER SELECTIONS.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 14/41


Correct


Part B


In the images below, which contains a disconformity?


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 15/41


Correct


Part C


What does the term unconformity mean?


Hint 1.


un = NOT; conform = go along with


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 16/41


Correct


Part D


In the following rock sequence, how much erosion might have occurred between rock layer A and rock layer B?


ANSWER:


Correct


Part E


What characteristic most directly DISTINGUISHES an angular unconformity from a nonconformity?


Hint 1.


The word angular is the key hint.


ANSWER:


a missing rock layer in a sequence that represents a period of deposition


an extra rock layer that represents a period of deposition


a missing rock layer in a sequence that represents a period of erosion or nondeposition


an extra rock layer that represents a period of erosion


at least 10,000 years


none or only a very small amount (Time does not equate to erosion.)


more time than it took to deposit rock layer B


at least 1 million years


more time than it took to deposit rock layer A


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 17/41


Correct


Part F


Which list best describes the events that would lead to the layering of sedimentary rocks in this diagram?


ANSWER:


Correct


GeoTutor: Constructing an Order of Sequence of Geologic Events – Relative Dating


The ordering of events in geological history has long been a difficult task, but once simple principles were determined observation and logic could be used to determine the order of events. With these principles, one cannot calculate the exact number of years ago an event occurred, but instead the sequence of events can be determined. This is referred to as relative dating. The principles are as follows:


1. The law of superposition: In sedimentary rocks, the rock bed on the bottom must be older than the rock bed on the top. 2. The principle of original horizontality: Sedimentary rocks were originally deposited as flat­lying, horizontal layers.


Angular unconformities represent missing time, whereas nonconformities do not.


Conformities represent missing rock layers.


Nonconformities separate parallel rock layers of the same rock type.


Nonconformities separate two different rock types, whereas angular unconformities form only between strata of the same rock type.


Angular unconformities separate rock layers along nonparallel surfaces.


deposition, erosion, deposition, erosion, deposition


erosion, deformation, erosion, deformation, erosion


deposition, deformation, deposition, deformation, deposition


erosion, deposition, erosion, deposition, erosion, deposition, erosion


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 18/41


3. The principle of cross­cutting relationships: Any rock or feature, cutting through another rock or feature, must be younger than the material through which it cuts. (For example, with faults, igneous intrusions such as dikes, or fractures, the first rock must be there for these secondary features to cut through.)


4. Inclusions: Any rock fragments included within another rock must be older than the rock in which they are included. (For example, if eroded fragments of one rock layer become part of another sedimentary rock layer, the rock with the included fragments must be younger than the fragments themselves.)


Part A ­ Basic Principles for Relative Geologic Dating


Below is a geologic structure that illustrates the various principles of relative dating. You will identify the basic principles used in relative geologic dating by dragging labels to their corresponding targets in the image below.


Drag the appropriate labels to their respective targets.


Hint 1. Inclusions in sedimentary rock layers


According to the principle of inclusions, the layer of rock that has inclusions from another rock layer must be younger.


Hint 2. A dike cutting through sedimentary rock layers


The rock layers that the dike cut through must have been there first. This is the principle of cross­cutting relationships.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 19/41


Correct


As you can see from above, using the logic of these principles when observing sedimentary rock, we can determine a sequence of events.


Now that we have investigated the principles of relative dating, we can use these principles to determine how to read the sequence of geologic events in a location.


Part B ­ Ordering of Geologic Events


The principles of relative dating can be used to understand the order of geologic events. A geologic event can be anything: the deposition of horizontal layers of sedimentary rock, the faulting or folding of rock layers, the tilting of rock layers, the erosion (or wearing away) of rock, the intrusion of volcanic rock within existing rock layers, and so on. Refer to these relative dating principles:


1. Inclusions: Any rock fragments included within another rock must be older than the rock in which they are included. (For example, if eroded fragments of one rock


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 20/41


layer become part of another sedimentary rock layer, the rock with the included fragments must be younger than the fragments themselves.) 2. The principle of cross­cutting relationships: Any rock or feature, cutting through another rock or feature, must be younger than the material through which it cuts. (For example, with faults, igneous intrusions such as dikes, or fractures, the first rock must be there for these secondary features to cut through.)


3. Angular Unconformity: It consists of tilted or folded sedimentary rocks that are overlain by younger, more flat­lying strata. An angular unconformity indicates that during the pause in deposition, a period of deformation (folding or tilting) and erosion occurred.


4. Tilting or deformation could occur to an otherwise horizontally layered sedimentary rocks. Most layers of sediment are deposited in a nearly horizontal position. Thus, when we see rock layers that are folded or tilted, we can assume that they must have been moved into that position by crustal disturbances after their deposition. In such an instance, the tilted structure will be younger than the orginal horizontal layers.


Order the five images below along the timeline based on the sequence of geologic events. To find the oldest, look for the image that shows the least geologic changes. To find the youngest, look for the picture that has the most geologic changes.


Rank from oldest to youngest.


Hint 1. Inclusions from rock layers above and below


In the picture where the gray layer first appears, the layer must be younger than the layers above and below because it has inclusions of both layers of rock within it according to the principle of inclusions. Therefore, this event must have happened after the picture without the gray layer. This can occur when igneous rock intrudes between layers of sedimentary rock and incorporates pieces of the rock layers above and below into the cooling magma.


Hint 2. The oldest and the youngest geologic features/events


The oldest geologic feature should have the least geologic changes and the youngest should have all features from the previous events.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 21/41


All attempts used; correct answer displayed


As you can see, you can apply the logic of the principles of relative dating to successfully sequence the order of geologic events in a scene. The principles allow you to tell the geologic story of a landscape.


Lab Activity 8.2.1 ­ Relative Dating


Now that you have practiced ordering geologic events that occurred within a scene or outcrop, you will relate the five geologic laws to this process. First, apply geologic laws to an outcrop in the order that they are invoked by events within said outcrop. Then examine a second scene, where you will identify the geologic laws that explain the relative orders of pairs of events.


Part A ­ Applying Geologic Laws in Order


Please rank from first to last the geologic laws that are used to determine the relative order of the four events that are labeled (but not ordered) in the drawing of the outcrop below.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 22/41


Please rank the geologic laws used for the history of this outcrop from first to last.


You did not open hints for this part.


ANSWER:


Part B ­ Supporting an Outcrop’s History with Geologic Laws


For each rectangle associated with a pair of geologic structures or events, please identify the name of the geologic law that determines which of the two events within the pair


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 23/41


occurred first.


Drag the appropriate labels to their respective targets.


You did not open hints for this part.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 24/41


Gigapan: Virtual Fieldwork—Relative Dating and Unconformities


Geologists can determine the geologic history of an area by describing rock outcrops and analyzing the layers of rock. Today you will be a geologist visiting a rock outcrop virtually. You will be able to zoom in and out of the Gigapan image to explore the outcrop and determine the relative ages of rock layers and the geologic history of the area by applying your knowledge of the principles of geology and unconformities.


The principles of geology that you will use in this example are:


The law of superposition: A sedimentary rock bed on the bottom must be older than the rock bed on the top. The principle of original horizontality: Sedimentary rocks were originally deposited as flat­lying, horizontal layers. The principle of lateral continuity: Sedimentary layers, when formed, extended horizontally in all directions.


You will also use your knowledge of unconformities, features created when deposition stopped, uplifting and erosion occurred, and, after a period of time, sedimentation began anew above the eroded layer. There are three main types of unconformities:


A nonconformity is found where igneous or metamorphic rocks have eroded and then sedimentary rock layers are deposited above. A disconformity is a break between parallel sedimentary rock layers above and below. Disconformities represent times when sediments were not deposited or were eroded. An angular unconformity is found where sedimentary layers were tilted and eroded and younger and more flat­laying sedimentary layers were deposited above.


In this exercise, you will use Gigapan technology to:


become familiar with interpreting rock outcrops, understand the sequence of events that occurred as these rocks formed and changed over time, and identify the location of an unconformity in this outcrop and provide evidence for its type.


Gigapan technology mosaics thousands of photos together into a single image, allowing you to zoom in and see the tiniest of details. Imagine zooming in on a grain of sand on a photo of a beach!


Instructions for all Parts:


1. Launch the Gigapan image http://www.gigapan.com/galleries/10030/gigapans/129421 2. You can zoom into the image to take a close look at the angular unconformity.


Instructions for Part A:


1. Scroll down and click on the Google Earth link on the Gigapan site to launch the Gigapan image in Google Earth. 2. Close the photo by clicking on Exit Photo to see your field site location in Google Earth. 3. Zoom in or out to determine your location. Also, on the upper right side, your will find the north arrow. If "N" is not aligned with "North" move it to North. This will ensure that the alignment of your field site is directly facing you in an east­west direction.


4. You can reopen the Gigapan image by clicking on Angular Unconformity, west of El Paso, Texas on the left pane of Google Earth. 5. Do not close Google Earth.


Part A ­ Locating your field site


As a geologist, you always want to first locate your field site on a map. It helps other geologists to locate the field site for future studies and helps you look for relationships with data from other nearby field sites. Now, determine where you are (your field site) in the world. Choose the map that best locates your field site.


http://www.gigapan.com/galleries/10030/gigapans/129421

2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 25/41


You did not open hints for this part.


ANSWER:


Instructions for Part B:


1. Go back to the Gigapan image for the Angular Unconformity, west of El Paso, Texas. 2. Examine the outcrop carefully. Make note of any features that would show up on a map (e.g., roads, trees, etc.). 3. Now switch back to Google Earth and zoom in or out to determine how the outcrop is oriented (runs north to south, runs northeast to southwest, etc.) compared to where you are standing and viewing the outcrop. If "N" is not aligned with "North" move it to North.


Part B ­ The orientation of the outcrop


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 26/41


Rock units tell us about Earth’s past, so if we find evidence of geologic processes that have directional components (direction of plate movement, folds and faults, mineral foliation, wind and water currents, etc.), we need to be able to accurately reconstruct those directions. Also, in terms of the scientific method, it helps other geologists to be able to recreate the field investigation step­by­step to confirm or refute any previous findings.


Imagine visiting this outcrop, standing at the location where the Gigapan image was taken, and observing the natural and built features around you. Choose the most accurate representation of the outcrop’s orientation and your vantage point (where you are standing in relation to the outcrop). The representations below depict you and the outcrop as viewed from above. Similar to how you identified the location of this outcrop in the previous part, use Google Earth at a multiple zoom levels. The yellow dot is the point where the Gigapan image was taken.


You did not open hints for this part.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 27/41


Instructions for Parts C and D:


1. Exit Google Earth and go back to the Gigapan image for Angular Unconformity, west of El Paso, Texas. 2. Examine the outcrop carefully, and make note of the orientation of the layers of sedimentation in this image. Are all of the rock layers running in the same direction? Does the formation contain layers running at different angles?


3. Recall that angular unconformities refer to the junction between sedimentary rocks at an angle and rocks that are more horizontal and represent a time when the rocks were uplifted and eroded. Can you see the evidence of uplift and erosion in the image?


Part C ­ Analysis of an outcrop sketch


Where you see layers of sedimentary rock at an angle in contact with rocks that are horizontal, they are separated by a surface called an angular unconformity. This erosion surface represents a time when rocks were eroded before new layers of rock were formed. This can also occur during a pause in deposition, when a period of deformation (such as folding or tilting) has occurred.


Choose the sketch that best represents the rock outcrop.


You did not open hints for this part.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 28/41


Part D ­ Making observations I


Simple yet thoughtful observation exposes the history of an outcrop. The sedimentary rocks in the Gigapan image were formed as sediment accumulated as layers that stacked atop older layers. As layers became lower in the stack sequence and covered by newer layers, they became rocks.


If this area had been under water, the shells of organisms would have become limestone, a rock that can't be identified visually but can be identified using field­based tests. Underwater movement of sediment may also create mixes of fine and coarse grains. This sediment becomes conglomerate, a rock clearly identifiable given its combined


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 29/41


coarse and fine grains. Over time, some layers would have become exposed as the water retreated and the rock layers above them were eroded. Additionally, some layers would have been tilted by tectonic forces.


Classify the observations according to the rock that they describe, or choose “Not enough information to tell.”


Drag the appropriate items to their respective bins. Each item may be used only once.


You did not open hints for this part.


ANSWER:


Part E ­ Making observations II


Choose the location of the unconformity.


You did not open hints for this part.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 30/41


Part F ­ Making observations III


Now that you have identified the unconformity in this outcrop, can you explain why it is an angular unconformity? Review the statements below, and indicate which are correct.


Select all that apply.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 31/41


You did not open hints for this part.


ANSWER:


Part G ­ Drawing conclusions from the timing of events


Review the outcrop again. Order the specific locations identified in the outcrop by their age. Note where the arrow, square, and circles are located.


Rank the areas identified in the cross section from oldest to youngest.


You did not open hints for this part.


ANSWER:


It is an angular unconformity because layers of sedimentary rock are above and below the unconformity and the layers above and below are not parallel.


It is an angular unconformity because it is at an angle to the ground surface instead of parallel.


The tilting of the layers of rock occurred before erosion of the unconformity surface.


It is an angular unconformity because the layers of sedimentary rock above and below the unconformity are at the same angle.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 32/41


Part H ­ Forming a conclusion: Determining the geologic history of an area from an outcrop


Geologists collect observations from field sites and then summarize their interpretations. It’s your turn to take everything you learned while exploring the rocks in this formation near El Paso, Texas, into a coherent story. Arrange the following geologic events in the order that they occurred.


Rank from oldest to youngest.


You did not open hints for this part.


ANSWER:


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 33/41


Interactive Animation: Radioactive Decay


When you have finished, answer the questions.


Part A


What happens during radioactive decay?


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 34/41


ANSWER:


Part B


What is the scientific definition of half­life?


ANSWER:


Part C


Two containers hold the same radioactive isotope. Container A contains 1000 atoms, and container B contains 500 atoms. Which of the following statements about containers A and B is true?


ANSWER:


Part D


A container holds 100 atoms of an isotope. This isotope has a half­life of 1.5 months. How many total atoms will be in the container after 3 months?


ANSWER:


Daughter isotopes turn into energy.


Parent isotopes turn into energy.


Energy turns into daughter isotopes.


Parent isotopes turn into daughter isotopes.


Daughter isotopes turn into parent isotopes.


the number of parent isotopes that will be lost during a single radioactive decay event


the number of daughter isotopes that will be gained during a single radioactive decay event


the amount of time over which the number of daughter isotopes increases by half


the amount of time over which the number of parent isotopes decreases by half


The rate of decay of atoms in container B is the same as the rate of decay of atoms in container A.


The rate of decay of atoms in container B is greater than the rate of decay of atoms in container A.


The rate of decay of atoms in container A is greater than the rate of decay of atoms in container B.


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 35/41


Part E


A container holds 100 atoms of an isotope. This isotope has a half­life of 1.5 months. How many atoms of the radioactive isotope will be in the container after 3 months?


ANSWER:


Part F


A rock sample contains 75 atoms of a parent isotope and 25 atoms of a daughter isotope. The half­life of the parent isotope is 100 years. How old is this rock?


ANSWER:


GeoTutor: Constructing an Order of Sequence of Geologic Events ­ Dating with Radioactivity ­ 2


You probably have read or seen stories about archeological findings that include organic remains of a 1000­year­old mummy or an ancient weapon made from stone, which is an inorganic material. Geologists and paleontologists calculate the age of these organic (contain carbon) and inorganic (do not contain carbon) materials by radiometric dating using the isotopes C­14 and U­235, respectively.


1. C­14 dating: This process is often known as radiocarbon dating. It is used to determine both historical and recent events of archeological artifacts of biological origin such as bone, cloth, wood, and plant fibers.


2. U­235 dating: This is used to determine the age of inorganic substances such as ancient rocks and minerals.


100 atoms


50 atoms


33 atoms


25 atoms


25 atoms


33 atoms


50 atoms


100 atoms


25 years old


50 years old


75 years old


100 years old


2/26/2016 Homework 5 Geologic Time


https://session.masteringgeology.com/myct/assignmentPrintView?assignmentID=1211587 36/41


Part A ­ Calculating the Age of a Fossil Based on the Number of Half­lives Elapsed


Each isotope has a unique half­life. The half­life of an isotope is the time taken for half of the starting quantity to decay (with a ratio of 1:1). After two half­lives, there will be one­ fourth of the original parent sample and three­quarters would have decayed to the daughter product (with a ratio of 1:3). After three half­lives, the ratio becomes 1:7, and so forth.


The graph, for instance, shows that assuming the half­life of a sample is 4 months, then in 4 months, there will be 0.5 gram of the parent element and 0.5 gram of the daughter element will be produced. In month 8 (which is two­half­lives), there will be only 0.25 gram of parent element left and 0.75 gram of daughter element; that is, one­fourth of the parent sample (in red) is left, and in month 12, there is only one­eighth of the parent element.


You attend a geology lab where you are asked to estimate the age of a fossil. The ratio of parent to daughter elements in the fossil sample is 1:7. You know that fossils are the remains of living organisms, which have some amount of C­14 isotope. The C­14 isotope, which has a half­life of 5730 years, begins to decay as the organism dies.


What would be your estimation of the fossil's age?


You did not open hints for this part.


ANSWER:


22,920


5730


2865


11,460


40,110


17,190


2/26/2016 Homework 5 Geologic Time


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Part B ­ Radiometric Dating of Organic and Inorganic materials


John is assisting a geologist who has traveled across the world and collected a few samples. He asks John to classify the samples that can be dated using carbon­14 and uranium­235 (or U­235). All organic materials contain carbon and are dated using C­14; inorganic materials are dated using any radioactive element, such as uranium, rubidium, potassium, and thorium, except carbon. Now, help John group the samples.


Drag the appropriate items to their respective bins. Each item may be used only once.


You did not open hints for this part.


ANSWER:


Chapter 18 Reading Quiz Question 2


Part A


Which geological principle states that even if most sedimentary rock layers are presently folded, they were deformed after deposition?


You did not open hints for this part.


2/26/2016 Homework 5 Geologic Time


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ANSWER:


Chapter 18 Problem 1 Multiple Choice


Part A


An unconformity is a buried ________.


ANSWER:


Chapter 18 Problem 2 Multiple Choice


Part A


Which of the following best characterizes an angular unconformity?


ANSWER:


principle of original horizontality


law of superposition


principle of cross­cutting relationships


principle of unconformities


principle of inclusions


surface of erosion separating younger strata above from older strata below


surface of erosion with older strata above and younger strata below


fault or fracture with older rocks above and younger rocks below


fault or fracture with younger strata above and older strata below


2/26/2016 Homework 5 Geologic Time


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Chapter 18 Problem 6 Multiple Choice


Part A


By applying the law of superposition ________ dates can be determined.


ANSWER:


Chapter 18 Problem 9 Multiple Choice


Part A


Sandstone strata and a mass of granite are observed to be in contact. Which of the following statements is correct geologically?


ANSWER:


Tilted strata lie below the unconformity, and bedding in younger strata above is parallel to the unconformity.


Horizontal lava flows lie below the unconformity, and horizontal, sedimentary strata lie above.


It is the discordant boundary between older strata and an intrusive body of granite.


Tilted strata lie below the unconformity with loose, unconsolidated soil above.


conventional


radiometric


relative


both relative and radiometric


The sandstone is younger if the granite contains sandstone inclusions.


The granite is older if the sandstone contains pebbles of the granite.


The granite is older if it contains inclusions of sandstone.


The sandstone is younger if it shows evidence of contact metamorphism.


2/26/2016 Homework 5 Geologic Time


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Chapter 18 Problem 28 True/False


Part A


A disconformity is an erosional unconformity with parallel beds or strata above and below.


ANSWER:


Chapter 18 Problem 12 Multiple Choice


Part A


A worm would stand a poor chance of being fossilized because ________.


ANSWER:


Chapter 18 Problem 51 Short Answer


Part A


The remains or traces of prehistoric life are called ________.


ANSWER:


True


False


worms have been rare during the geologic past


worms have no hard parts


worms contain no carbon­14


all of these


2/26/2016 Homework 5 Geologic Time


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Chapter 18 Problem 16 Multiple Choice


Part A


Which of the following is not a very long­lived, radioactive isotope?


ANSWER:


Score Summary: Your score on this assignment is 47.1%. You received 7.06 out of a possible total of 15 points, plus 0 points of extra credit.


C­14


K­40


U­238


Rb­87

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