D15.8 Radiometric Dating

Jia Zhou; John Moore; Etienne Garand

D15.8 Radiometric Dating

Several radioisotopes have half-lives and other properties that make them useful for radiometric dating, the process of determining an object’s date of origin. The objects of interest can be geological formations, archaeological artifacts, or formerly living organisms. Radiometric dating has been responsible for many breakthrough scientific discoveries about the geological history of the earth, the evolution of life, and the history of human civilizations.

Radiometric Dating Using Carbon-14

Radiocarbon dating or carbon-14 dating can provide reasonably accurate dating of carbon-containing substances up to ~50,000 years old.

Naturally occurring carbon consists of three isotopes: ¹²C, which constitutes 99% of the carbon on earth; ¹³C, about 1% of the total; and 1 part per trillion (0.0000000001%) of ¹⁴C. ¹⁴C is formed in the upper atmosphere by the reaction of nitrogen atoms with neutrons:

$_{\;7}^{14}\text{N} + \;_0^1\text{n} \;\longrightarrow\; _{\;6}^{14}\text{C} + \;_1^1\text{H}$

All isotopes of carbon react with oxygen to produce CO₂. In the atmosphere, the ratio of ¹⁴CO₂ to ¹²CO₂ has been nearly constant for a long time, as shown by analysis of carbon-containing gas samples trapped in Greenland ice sheets.

The incorporation of ¹⁴CO₂, ¹³CO₂ and ¹²CO₂ into plants is a regular part of photosynthesis. Therefore, a living plant is constantly exchanging carbon with its environment, meaning that the ¹⁴C:¹²C ratio found in a living plant is the same as the ¹⁴C:¹²C ratio in the atmosphere. But when a plant dies, the carbon exchange with the atmosphere stops. Because ¹²C is a stable isotope and does not undergo radioactive decay, the amount of ¹²C in the dead plant does not change. However, ¹⁴C undergoes β decay with a half-life of 5730 years (β decay involves emission of an high energy electron from a nucleus):

$_{\;6}^{14}\text{C} \;\longrightarrow\; _{\;7}^{14}\text{N} +\; _{-1}^{\;0}\beta$

Thus, the ¹⁴C:¹²C ratio gradually decreases after the plant dies, and this provides a measure of the time that has elapsed since the death of the plant. For example, if the ¹⁴C:¹²C ratio in a wooden object found in an archaeological site is half what it is in a living tree, this indicates that 5730 years have elapsed since the death of the tree from which the wooden object was made. Highly accurate determinations of ¹⁴C:¹²C ratios can be obtained from very small samples (as little as a milligram) by the use of a mass spectrometer.

This process works for other organisms as well, since they also constantly exchange carbon (by eating plants or eating others that eat plants) until they die.

**Figure: Radiocarbon dating**. Along with the stable ¹²C, radioactive ¹⁴C is constantly exchanged by living plants and animals with the environment, and the ¹⁴C:¹²C ratio remains at a constant level within them while they are alive. After death, the ¹⁴C that remains in the organism decays and the ¹⁴C:¹²C ratio begin to decrease. Comparing this ratio to the ratio in living organisms allows determination of how long ago the organism lived (and died).

Activity: Radiocarbon Dating

The Dead Sea Scrolls are ancient religious manuscripts discovered in 1946 and 1947. The first radiocarbon dating of the scrolls was in 1950. A tiny piece of paper (produced from formerly living plant matter) taken from the Dead Sea Scrolls was found to have an activity of 10.8 disintegrations per minute per gram of carbon. If the initial carbon-14 activity was 13.6 disintegrations per min per gram of carbon, estimate when the Dead Sea Scrolls were written. (The half-life of carbon-14 is 5730 years)

Write in your notebook, then left-click here for an explanation.

Activity (radioactive decay rate) is proportional to the amount of carbon-14 left in the paper:

A = λN

Therefore:

$t = -\dfrac{1}{\lambda}\ln\left(\dfrac{\text{N}_t}{\text{N}_0}\right)$

becomes:

$t = -\dfrac{1}{\lambda}\ln \left(\dfrac{\frac{A_t}{\lambda}}{\frac{A_0}{\lambda}}\right) = -\dfrac{1}{\lambda}\ln\left(\dfrac{A_t}{A_0}\right)$

Here, time = 0 represents the time when the plants were cut to make the paper, and time = t represents the “current” time of the experiment (1950).

The decay constant can be determined from the half-life of carbon-14:

$\lambda = \dfrac{\ln (2)}{t_{1/2}} = \dfrac{\ln (2)}{5730\ \text{y}} = 1.21 \times 10^{-4} \frac{1}{\text{y}}$

This gives us:

$t = -\dfrac{1}{\lambda}\ln \left(\dfrac{A_t}{A_0}\right) = -\dfrac{1}{1.21 \times 10^{-4}\frac{1}{y}} \ln \left(\dfrac{10.8 \;\frac{\text{disintegrations}}{\text{(min)(g of C)}}}{13.6\;\frac{\text{disintegrations}}{\text{(min)(g of C)}}}\right) = 1910\ \text{y}$

Therefore, the Dead Sea Scrolls were written 1910 years before 1950, or at 40 CE. (Many carbon-14 dating experiments since 1950 have shown that the pages from the Dead Sea Scrolls were written or copied on paper made from plants that died between 100 BCE and 50 CE.)

The accuracy of radiocarbon dating assumes that the ¹⁴C:¹²C ratio in a living plant is the same now as it was in an earlier era, but this is not always valid. For example, right now, due to the increasing accumulation of CO₂ (largely ¹²CO₂) in the atmosphere, caused by combustion of fossil fuels in which essentially all of the ¹⁴C has decayed, the ¹⁴C:¹²C ratio in our atmosphere is decreasing. This in turn affects the ¹⁴C:¹²C ratio in currently living organisms on earth. Fortunately, we can use other data, such as tree dating via examination of annual growth rings, to calculate correction factors. With these correction factors, more accurate dates can be determined. In general, radioactive dating only works for about 10 half-lives; therefore, the limit for carbon-14 dating is about 57,000 years.

Radiometric Dating Using Nuclides Other than Carbon-14

Radiometric dating using radioactive nuclides with half-lives longer than that of carbon-14 can date events older than 57,000 years ago.

For example, uranium-238 can be used to estimate the ages of some of the oldest rocks on earth. Since ²³⁸U has a half-life of 4.5 billion years, it takes that amount of time for half of the original ²³⁸U to decay by a series of nuclear reactions into ²⁰⁶Pb. In a rock sample that does not contain appreciable quantities of ²⁰⁸Pb, the most abundant isotope of lead, we can assume that lead was not present when the rock was formed. Therefore, by measuring and analyzing the ratio of ²³⁸U:²⁰⁶Pb, we can determine the age of the rock. This assumes that all of the ²⁰⁶Pb present came from the decay of ²³⁸U. If there is ²⁰⁶Pb from sources other than ²³⁸U, which is often indicated by the co-presence of other lead isotopes in the sample, it is necessary to make adjustments in the calculations.

Potassium-argon dating uses a similar method. ⁴⁰K decays to form ⁴⁰Ar with a half-life of 1.25 billion years. If a rock sample is crushed and the amount of ⁴⁰Ar gas that escapes is measured, determination of the ⁴⁰K:⁴⁰Ar ratio yields the age of the rock. Other methods, such as rubidium-strontium dating (⁸⁷Rb decays into ⁸⁷Sr with a half-life of 48.8 billion years), operate on the same principle.

To estimate the lower limit for the earth’s age, scientists determine the age of various rocks and minerals, making the assumption that the earth is older than the oldest rocks and minerals in its crust. The oldest rocks on earth that has been dated are the Jack Hills zircons from Australia, found by uranium-lead dating to be almost 4.4 billion years old.

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