Modeling U-Series Concordia/Discordia Using STELLAKirsten M. Menking, Department of Geology and Geography, Vassar College, Poughkeepsie, NY 12604
STELLA
Structural Thinking Experimental Learning Laboratory with Animation - icon-based dynamical systems modeling tool developed by High Performance Systems, Inc.
Boxes represent reservoirs
Arrows represent flows into and out of reservoirs
Dependencies of variables are represented with pink linking arrows
Converters, hold values of constants and equations.
reserv oir
f lows
conv erter
Paper No. 60-11
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STELLA model of a three-isotope decay series (above) and experiments with different half-lives for the radioactive parent and daughter isotopes (below). Decay flows = the number of isotopes remaining at time t * the decay constant. Decay constants (λ) calculated from half-lives by λ = ln(2)/half-life.
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IntroductionU-Series dating techniques are widely used to determine the absolute ages of some of Earth's oldest rocks, but the concordia/discordia diagram can be quite difficult for students to grasp. In particular, the fact that differing amounts of lead and uranium loss from minerals such as zircon can be used to determine not only the original formation age, but also the time of metamorphism of a rock like granite, is a challenging concept. Making use of previous workers' web-published excercises on radiometric decay, I have produced a STELLA-based lab exercise to develop students' understanding of this important chronologic technique. Students create models of the two isotopic decay systems, 238U --> 206Pb and 235U --> 207Pb, and run these models for 4.5 billion years to create the concordia diagram. They then carry out experiments in which they "add" or "remove" varying amounts of lead or uranium in simulation of metamorphism. The uranium-lead ratios at the end of the simulation allow the discordia line to be plotted on top of the concordia diagram and the ages of original crystallization and metamorphism to be determined from the points of intersection of the two lines. In the course of the lab, students are introduced to the concepts of exponential decay and secular equilibrium as well as modeling concepts such as the creation of if-then statements.
-dN1
dt= λ1N1
dN2
dt= λ1N1 - λ2N2
λ1
λ2
N2
N1 =
N2 = λ1
λ2 − λ1N1e-λ1t
0solution:
N1 = N1e-λ1t0but,
N2 = λ1
λ2 − λ1N1so,
λ1
λ2 − λ1
N2
N1 =rearranging:
if λ1 << λ2, then λ2 - λ1 = λ2, so
D* = N1 - N1 - N2 but since λ1 << λ2, N2 = 00
D* = N1eλ1t - N1
Secular EquilibriumThe complicated Uranium decay series (4., right) can be simplified due to the fact that both series exhibit secular equilibrium. This condition is met when the half-life of a radioactive parent isotope at the beginning of a decay series is much longer than the half-lives of any intermediate daughter isotopes. The mathematics to the left illustrate this point for a simple three-isotope system in which a radioactive parent (N1) decays to a radioactive daughter (N2), which in turn decays to a stable daughter (D*). The change in the population of parent isotopes with time (-dN1/dt) is dependent on the decay constant of the parent isotope (λ1) and the number of parents remaining at time t. For the radioactive daughter, N2, the change in its population (dN2/dt) is a function of the production of new daughters from the decay of radioactive parents (λ1N1) minus the loss of radioactive daughters due to decay to the stable daughter (λ2N2). The solution to this pair of differential equations gives the curious result that λ1N1 = λ2N2 = a constant. This result can be generalized to a system with n species, in which case, λ1N1 = λ2N2 = ... = λnNn.
The number of stable daugthers at any time (D*), is the difference between the initial number of radioactive parents (N1) and the current number of radioactive parents (N1) and radioactive daughters (N2). Since N2 = (λ1/λ2)*N1 and λ1 << λ2, N2 is effectively zero and can be ignored. Thus, when the conditions of secular equilibrium are met, the decay series can be treated as though the radioactive parent isotopes decay directly to stable daughters.
0 λ1N1 = λ2N2or, and N2 =
λ1
λ2N1
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Decay series for 238U and 235U (above left). Primary decay series shown in orange. Half-lives of isotopes shown below isotope name. By = billion years, ky = kiloyears, d = days, h = hours, m = minutes, s = seconds, ms = milliseconds. Note that in all cases, the half-life of the initial decay is much longer than that of any of the intermediate daughter products such that secular equilibrium can be assumed. STELLA representations of U-series decay (above right), making use of secular equilibrium simplification.
Atom
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umbe
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222Rn3.8 d
226Ra1.6 ky
230Th75 ky
238Th24 d
234Pa1.2 m
234U248 ky
238U4.5 By
218Po3 m
218At2 s
218Rn35 ms
214Po0.2 ms
214Bi20 m
214Pb27 m
206Pbstable
206Po138 d
210Bi5 d
210Pb22 y
206Tl4.2 d
206Hg7.5 m
210Tl1.32 m
Neutron Number
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238U Decay Series
231Th26 h
227Th17 d
231Pa34 ky
235U0.7 By
227Ac22 y
223Fr22 m
223Ra11.4 d
219Rn3.96 s
219At56 s
215Bi8 m
215Po1.8 ms
215At0.1 ms
211Bi2.14 m
211Pb36.1 m
211Po0.56 s
207Pbstable
207Tl4.77 m
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Neutron Number
235U Decay Series
206Pb/238U
238U 206Pb
238U half-life
238U decay constant
238U decay
207Pb/235U
207Pb235U
235U decay
235U decay constant
235U half-life
4.Discordia/ConcordiaThe U-series concordia/discordia technique allows us to determine not only the original crystallization age of a rock, but also the age of last metamorphism. In the diagram below, a rock moving along the concordia diagram from its initial time of formation 4.5 billion years ago lost lead at 3.5 billion years ago. Lead loss occurred along the red dashed line connected to the origin of the graph (a sample that lost all of its lead would plot at the origin itself). After the episodic lead loss, the rock evolved along a new concordia parallel to the initial one toward point P'. This point lies along a discordia (dashed green line) connecting the age of the rock to the amount of time that has elapsed since the lead loss occurred (4.5 billion years - 3.5 billion years = 1.0 billion years).
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U-series Concordia diagram
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Decay 2
207Pb/235U
235U decay constant
235U half-life
207Pb Outflow
235U Outflow
235U Inflow
207Pb235U
Decay
206Pb Outflow
238U decay constant
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238U Inflow
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238U Outflow
206Pb238U
Modeling Discordia in STELLATo simulate a metamorphic event that results in lead loss, uranium loss, or uranium gain, outflow and inflow arrows are added to the simple U-series concordia model. Outflows and inflows are activated using an if-then statement, and allow varying amounts of each isotope to subtracted or added.
For example, the logical statement governing lead loss might read as follows:
IF(TIME=1500)THEN(0.1*Lead_206/DT)ELSE(0)
This statement removes 10% of the total 206Pb reservoir at time = 1500 million years. Similar statements govern uranium loss or addition.
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U-series Concordia diagram
Resulting Concordia diagram (below) when both Uranium reservoirs begin with 1 million atoms, both Lead reservoirs start out empty, and the model is run for 4.5 billion years (age of the Earth). Orange points represent 0.5 billion year time increments. The longer half-life for 238U relative to 235U is reflected in the x and y-axis values, since the 206Pb/238U ratio grows more slowly than the 207Pb/235U. The disparity in half-lives can also be seen in the curling of the graph toward parallelism with the 207Pb/235U axis.
5.
References• Dalrymple, G.B., 1991, The Age of the Earth, Stanford, CA, Stanford University Press, Chapter 3: Modern Radiometric Methods: How They Work.
• Faure, G., 1986, Principles of Isotope Geology (2nd Ed.), New York, John Wiley and Sons, Chapter 4: Radioactive Decay and Growth and Chapter 18: The U, Th-Pb Methods of Dating.
• http://www.ties.k12.mn.us/envision/student/lessons97/radioactivity
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Secular equilibrium experiments. In the example above, the half-life of the radioactive daughter exceeds that of the parent such that secular equilibrium is not achieved. Note that the curves representing the number of isotopes decaying do not converge. In other words, λ1N1 = λ2N2.
In the example below, the parent half-life greatly exceeds that of the radioactive daughter, such that λ1N1 = λ2N2 within a short period of time. Secular equilibrium!
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Acknowledgments:I gratefully acknowledge the support of the National Science Foundation, which funded this work through the Course Curriculum and Laboratory Improvement Adaptation and Implementation track (Grant #0087996).
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Experiments in Metamorphism
Concordia curvePb loss or U gainU loss
ResultsThe figure below shows the result of a model run in which 30% of the lead that had accumulated by 1.5 billion years was removed instantaneously. By the end of the 4.5 billion year run, the 207Pb/235U ratio is lower than if no lead loss had occurred.
The figure to the right shows the results of a series of experiments in which varying amounts of lead or uranium were lost or gained. Lead loss and uranium gain are effectively the same thing, and both create points that fall below the discordia curve. The experiments shown here were for 10%, 20%, and 30% lead loss at 1.5 billion years into a 3.5 billion year model run. The points define the discordia line, which projects to the time of original crystallization of the rock (in this case 3.5 billion years) and the time since metamorphism occurred (2 billion years ago). Experiments with uranium loss lead to points that plot above the concordia curve, but when a straight line is extrapolated through these points, it intersects the concordia curve in the same locations, because the timing of original crystallization and metamorphism remains the same between the lead loss and uranium loss experiments.
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U235Pb207
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30% loss of lead at 1.5 billion years
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