Description
6.2 Interactive Learning Activity
Associated Objectives
- Investigate radioactivity and radiometric dating, utilizing the scientific method and an interactive simulation
Radioactive Dating Game
In this activity, you will apply the scientific method to to investigate radioactive decay and its application to radiometric dating. . The activity involves experimentation using a web-based interactive simulation. The URL for the simulation is provided in the activity file.
Notes on the simulation:
- This simulation is optimized for use on computers (MACs or PCs) and may not run on some tablets, notebooks, cell phones, or other devices
- Running the simulation will require an updated version of?Java?software (free). If you do not have (or are not sure if you have) Java on your computer, go to?the Java website (Links to an external site.)
- Having trouble getting the simulation to run? Consult this PhET Simulation Troubleshooting Guide Download PhET Simulation Troubleshooting Guide
Activity Instructions
EDS 1021
Week 6 Interactive Activity
Radioactive Dating Game
Objective
Using a simulation, apply the scientific method to investigate radioactive decay and its
application to radiometric dating.
Background Reading
Before attempting the activity, review the topics Half-Life, Radiometric Dating, and Decay
Chains in Chapter 12 of The Sciences.
Introduction to the Simulation
1. After completing the background reading for this assignment, go to the Radioactive Dating
Game simulation on the PhET simulations website at:
http://phet.colorado.edu/en/simulation/radioactive-dating-game. Click the play arrow on
the simulation graphic to run the web-based simulation or click DOWNLOAD to run the
simulation locally on your device.
Simulation requirements: This interactive simulation is optimized for use on computers
(MACs or PCs) and may not run on some tablets, notebooks, cell phones, or other devices.
Running the simulation will require an updated version of Java software (free). If you do not
or are not sure if you have Java on your computer, go to the Java Website. If you cannot get
the simulation to run, consult The PhET Simulation Troubleshooting Guide on the course
website.
2. Explore and experiment on the four different tabs (areas) of the simulation. While
experimenting, think about how the concepts of radioactive decay are being illustrated in
the simulation.
a. Half-Life tab Observe a sample of radioactive atoms decaying – carbon-14, uranium-
238, or ? (a custom-made radioactive atom). Clicking on the add 10 button adds 10
atoms at a time to the decay area. There are 100 atoms in the bucket; so, clicking the
add 10 button 10 times empties the bucket into the decay area. Observe the pie chart
and time graph as atoms decay. You can pause or step the simulation as atoms decay,
and Reset the simulation, using buttons at the bottom of the screen.
b. Decay Rates tab Similar to the half-life tab, but different! Atom choices are carbon-14
and uranium-238. The bucket has a total of 1,000 atoms. Drag the slide bar on the
bucket to the right to increase the number of atoms added to the decay area. Observe
the pie chart and time graph as atoms decay. Note that the graph for the Decay Rates
tab provides different information than the graph for the Half-Life tab. You can pause or
step the simulation as atoms decay, and Reset the simulation, using buttons at the
bottom of the screen.
c. Measurement tab Use a probe to virtually measure the amount of radioactive
material within an object or in the atmosphere. The probe can be set to detect the
decay of either carbon-14 or uranium-238 atoms. Follow prompts on the screen to run a
simulation of a tree growing and dying, or of a volcano erupting and creating a rock, and
then measuring the decay of atoms within each object.
d. Dating Game tab Use a probe to virtually measure the percentage of radioactive
atoms remaining within various objects and estimate the ages of objects by applying the
concept of half-life. The probe can be set to either detect carbon-14, uranium-238, or
other mystery elements that may be contained in the objects. Drag the probe over an
object, select which element to measure, and then slide the arrow on the graph to
match the percentage of atoms measured by the probe. The time (t) shown for the
matching percentage can then be entered as the estimate in years of the objects age.
e. Pause button ( I I ) Simulation is running when this is showing; press to pause the
simulation.
f. Play arrow ( > ) Simulation is paused when this is showing; press to run the
simulation.
3. After getting oriented to the simulation, follow the steps below to perform four different
experiments. Before beginning, be prepared to write down hypotheses and observations
for the experiments.
Experiments
Experiment 1: Half-Life
In this experiment, you will visualize the radioactive decay of atoms and investigate the concept
of half-life.
Before completing the experiment, write down a hypothesis, based on your current
understanding, that makes specific predictions for how the decay of a radioactive substance will
progress over time.
1. Experiment setup: click on the Half-Life tab at the top of the simulation screen.
2. Experiment procedure:
Construct a table like the one below. Complete the following steps for parts I and II of the
experiment to complete the table.
Part I – Carbon-
a. Make sure that Carbon-14 is selected in the Choose Isotope box. Click the pause
button ( I I ) at the bottom of the screen so that it shows the play arrow ( > ). Click
the Add 10 button below the Bucket o Atoms ten times to empty the bucket and
place 100 carbon-14 atoms in the decay area.
b. The half-life of carbon-14 is about 5,700 years. Based on the definition of half-life, if
you left these 100 carbon-14 atoms to sit around for 5,700 years, what would you
predict to be the number of carbon-14 atoms that would radioactively decay
during that time? Write your answer down.
c. Click the play arrow. As the simulation runs, carefully observe what is happening to
the carbon-14 atoms in the decay area, and the graphs at the top of the screen (both
the pie chart and the time graph).
d. After all atoms have decayed, click the pause button, and the Reset All Nuclei
button in the decay area.
e. Repeat steps c and d until you have a good idea of what is going on. Then, write
down a specific description of what you observed happening, both in the decay
area and on the pie chart and time graph, while the simulation is in play mode.
f. Repeat step c again, but this time, watch the graph at the top of the window
carefully, and click pause when Time reaches 5,700 years, i.e., when the carbon-
14 atom moving across the graph reaches the dashed line labeled Half-Life. If you
dont pause the simulation on or very close to the dashed line, click the Reset All
Nuclei button and repeat step c again.
g. Once you have paused the simulation in the correct spot, record the number of
carbon-14 nuclei that have decayed into nitrogen-14 (the number next to #14N, to
the left of the pie chart).
h. Click the Reset All Nuclei button in the decay area.
i. Repeat steps f through h for two more trials, to record a total of three values for
step g.
Part II Uranium-238
a. Click Reset All below the Choose Isotope box, then yes in the box that pops up. Click
on the radio button for Uranium-238 in the Choose Isotope box. Click the pause
button at the bottom of the screen so that it shows the play arrow. Click the Add 10
button ten times to empty the bucket and place 100 Uranium-238 atoms in the
decay area.
b. The half-life of Uranium-238 is 4.5 billion years!* Based on the definition of half-life,
if you left these 100 Uranium-238 atoms to sit around for 4.5 billion years, write
down your prediction of the number of Uranium-238 atoms that will radioactively
decay over that time.
c. Click the play arrow. Watch the graph at the top of the window carefully, and click
pause when Time reaches 4.5 billion years, i.e., when the Uranium-238 atom
moving across the graph reaches the dashed line labeled Half Life. If you dont pause
the simulation on or very close to the dashed line, click the Reset All Nuclei button
and repeat step c.
d. Once you have paused the simulation in the correct spot, record the number of
Uranium-238 nuclei that have decayed into Lead-206 (the number next to #206Pb to
the left of the pie chart).
e. Click the Reset All Nuclei button in the decay area.
f. Repeat steps c through e for two more trials, to record a total of three values for
step d.
Number of atoms that have
decayed when
Time = Half LifeRadioactive
Element
Number of atoms in
the sample at Time = 0
Prediction of # atoms that
will decay when time
reaches one half-life Trial #1 Trial #2 Trial #3
Carbon-14 100
Uranium-238 100
Experiment 1 – Results and Conclusions
1. In Part I of the experiment (and in nature), carbon-14 radioactively decays to nitrogen-14.
Based on what you read in Chapter 12 of The Sciences about the three types of radioactive
decay, name the specific type of radioactive decay taking place in Part I of the experiment.
2. Based on your observations and data collected while conducting Experiment 1:
a. Formulate a written discussion that describes the nature of radioactive decay i.e., is
the process random, exact, or something else, and can you make any analogies between
radioactive decay and other processes you observe in your everyday life?
b. Does the data collected in parts I and II of the experiment validate or negate the
concept of radioactive half-life? Support this conclusion by formulating a written
comparison between your predictions from step b for the number of atoms that will
radioactively decay over one half-life and the values you recorded in the trials.
* Unlike carbon-14, which undergoes only one radioactive decay to reach the stable nitrogen-14, uranium-238 undergoes many
decays into many intermediate unstable elements before finally getting to the stable element lead-206. (See the decay chain
for uranium-238 in Chapter 12 for details).
Experiment 2: Decay Rates
In this experiment, you will again visualize the radioactive decay of atoms, and you will also
make some additional quantitative measurements of the decay. Your hypothesis from
Experiment 1 also applies to this experiment.
1. Experiment setup: click on the Decay Rates tab at the top of the simulation screen.
2. Experiment procedure:
Construct a table like the one below. Complete the following steps for parts I and II of the
experiment to complete the table.
Part I Carbon-14
a. Click the Reset All button below the Choose Isotope box.
b. In the Choose Isotope area, click the button next to carbon-14.
c. Drag the slide bar on the bucket of atoms all the way to the right. This will put 1,000
radioactive nuclei into the decay area. When you let go of the slide bar, the simulation
will start right away. Watch the graph at the bottom of the screen until all atoms have
decayed.
d. From the graph, record the percentage of carbon-14 nuclei remaining at times
equivalent to 1, 2, and 3 half-lives of carbon-14 (a total of three percentage values).
Recall that the half-life of Carbon-14 is about 5700 years.
Part II Uranium-238
a. In the Choose Isotope area on the right side of the screen, click the button next to
Uranium-238.
b. Repeat step c of Part I for uranium-238.
c. From the graph, record the percentage of uranium-238 nuclei remaining at times
equivalent to 1, 2, and 3 half-lives of uranium-238 (a total of three percentage values).
Recall that the half-life of uranium-238 is about 4.5 billion years.
Percentage of the element remaining after:Radioactive
Element 1 half-life 2 half-lives 3 half-lives
Carbon-14
Uranium-238
Experiment 2 – Results and Conclusions
Does the data collected in parts I and II of the experiment validate or negate the concept of
radioactive half-life? Support this conclusion by discussing the trends in the number of
radioactive nuclei remaining after 1, 2, and then three half-lives had passed.
Experiment 3: Measurement
In this experiment, you will use a probe to detect the decay of radioactive material within a
rock and a tree.
Before completing the experiment, write down a hypothesis, based on your current
understanding, that predicts how the simulation should be utilized to detect each objects age.
1. Experiment setup: click on the Measurement tab at the top of the simulation screen.
2. Experiment procedure:
Part I Tree
a. Under Choose an Object, click on the button for Tree. In the Probe Type box, click on
the buttons for Carbon-14, and Objects. This sets up a probe to measure radioactive
decay of any carbon-14 in the tree. Note that the probe can only detect the element for
which it is set.
b. Click Plant Tree at the bottom of the screen. As the simulation runs, observe that the
tree grows and lives for about 1,200 years, then dies and begins to decay. Observe the
probe reading (upper left box) and graph (upper right box) at the top of the screen
showing the percentage of carbon-14 in the tree over time. Write down your
observations of what is taking place in the visual scenario, the probe reading, and the
graph.
c. Click either of the two Reset buttons on the screen. In the Probe Type box, set the
probe to measure uranium-238 instead of carbon-14. So, now the probe is detecting the
decay of any uranium-238 in the tree.
d. Click Plant Tree and again observe the probe reading and graph as the simulation runs.
Write down your observations of the probe reading and graph.
Part II Volcanic Rock
a.
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