Actinium-225

Actinium-225 (225Ac, Ac-225) is an isotope of actinium. It undergoes alpha decay to francium-221 with a half-life of 10 days, and is an intermediate decay product in the neptunium series (the decay chain starting at 237Np). Except for minuscule quantities arising from this decay chain in nature, 225Ac is entirely synthetic. The decay properties of actinium-225 are favorable for usage in targeted alpha therapy (TAT); clinical trials have demonstrated the applicability of radiopharmaceuticals containing 225Ac to treat various types of cancer. However, the scarcity of this isotope resulting from its necessary synthesis in cyclotrons limits its potential applications. Actinium-225 has a half-life of 10 days and decays by alpha emission. It is part of the neptunium series, for it arises as a decay product of neptunium-237 and its daughters such as uranium-233 and thorium-229. It is the last nuclide in the chain with a half-life over a day until the penultimate product, bismuth-209 (half-life 2.01e19 years). The final decay product of 225Ac is stable 205Tl. As a member of the neptunium series, it does not occur in nature except as a product of trace quantities of 237Np and its daughters formed by neutron capture reactions on primordial 232Th and 238U. It is much rarer than 227Ac and 228Ac, which respectively occur in the decay chains of uranium-235 and thorium-232. Its abundance was estimated as less than 1.1e−19 relative to 232Th and around 9.9e−16 relative to 230Th in secular equilibrium. Actinium-225 was discovered in 1947 as part of the hitherto unknown neptunium series, which was populated by the synthesis of 233U. A team of physicists from Argonne National Laboratory led by F. Hagemann initially reported the discovery of 225Ac and identified its 10-day half-life. Independently, a Canadian group led by A. C. English identified the same decay scheme; both papers were published in the same issue of Physical Review. As 225Ac does not occur in any appreciable quantities in nature, it must be synthesized in specialized nuclear reactors.