Radioactive Equilibrium

An equilibrium as old as the Earth

Establishing a radioactive equilibrium
The radioactive equilibrium takes about 2 million years to form in the lineage of uranium 238, at which point the activities of these descendants become equal to that of uranium 238. The short half-lives of the first two descendants, thorium 234 and protactinium 234, mean that this equilibrium is reached quickly. It takes much longer for the next descendants, uranium 234 (with a half-life of 246,000 years) and thorium 230 (with a half-life of 75,000 years) to reach equilibrium. Radium and radon, the next descendants in the chain, have much shorter half-lives, and reach equilibrium at about the same time as the thorium. Two million years represent a brief instant for uranium 238, whose half-life is 4.5 billion years. The activity of the ancestor nucleus will not even have had time to diminish.

Radioactive lineage is the term given to the chain of successive radioactive disintegrations that some nuclei undergo. In nature, radioactive lineage is particularly relevant for three heavy elements with half-lives of the order of billions of years: uranium 238, uranium 235 and thorium 232. The descendants of these three nuclei, present in trace quantities in rocks, make a substantial contribution to the natural levels of radioactivity.

Over the 4.5 billion years of the Earth’s history, all three of these decay chains have reached equilibria between the parent nucleus and the various descendants. The ratios evolve very slowly, ensuring that at any given moment the number of nuclei being formed is identical to the number of nuclei decaying. The activities are all practically invariant, and equal to the activity of the ‘ancestor’ nucleus.

The establishment of these so-called ‘secular’ equilibrium only takes place after a transition period. A classic example of this is uranium 238, an isotope that has a much longer half-life than any of the unstable nuclei it decays into. The decay of uranium 238 is so slow, in fact, that it is almost as though it was powered by a constant dripping, every drop gradually increasing the instability.

The longest-lived descendant of uranium 238 is uranium 234, a radioisotope with a half-life of 245,000 years; a long period of time that is still only one twenty-thousandth of the 4.5 billion year half-life of uranium 238. After a few half-lives of uranium 234 – about a million years later – the equilibrium we see today was established.

This secular equilibrium can occasionally be disrupted when one of the intermediary nuclei leaves the area where its ancestors are confined. These local disruptions are important to consider in the use of dating techniques.

Masses of the descendants of uranium 238 at equilibrium
The law of radioactive equilibrium states that the activities of the descendants of uranium 238 must be equal to the activity of the ancestor nucleus: 12.4 million becquerels per tonne. One of the consequences of this equilibrium law is that the ratio between the masses in which the descendants are present is proportional to the ratio that exists between their half-lives. These periods are very diverse and all much smaller than the period of uranium 238 (4.47 billion years), and the activities are also far smaller: uranium 234 has an activity of 54 grams per tonne, thorium 230 has an activity of 16g and radium’s activity is only of 0.34g.

A good example of equilibrium disruption is that of radon, one of uranium’s gaseous descendants that can escape from the minerals it gets trapped in. In the tunnel of uranium mines, fans can accelerate the diffusion of radon into the atmosphere. Considering the mine and the atmosphere as one system, the secular equilibrium is still maintained. In the mine, however, uranium’s descendants stop at radium – the parent of radon. The lineage continues outside of the mine, though the equilibrium has been disrupted in both areas.

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