Correction for calcium interference in the 40Ar/39Ar dating method

Since the inception of the ⁴⁰Ar/³⁹Ar dating method, it has been recognized that fast neutrons can interact with nuclides in the sample beyond ³⁹K, resulting in the production of interfering argon isotopes. Correction factors for these side effects have been proposed from many nuclear reactors globally. However, current practice does not always involve the monitoring of these correction factors for every sample batch, but is reliant on previous results instead. This approach is justified by the limited variability observed in the (³⁶Ar/³⁷Ar)_Ca and (³⁹Ar/³⁷Ar)_Ca correction factors, and such limited variability is acceptable for samples with high K/Ca ratio. For low K/Ca samples, however, even minor variations in the correction factors can significantly impact the accuracy of the results. Here, we evaluate the performance of optical grade CaF₂ crystals and spectrally pure-grade CaF₂ to monitor the correction factor for the calcium interference. The results demonstrate that the optical grade CaF₂ crystals yield consistently reliable calcium correction factors when subjected to stepwise heating and single grain total fusion. Therefore, we recommend the use of optical grade CaF₂ crystals for monitoring potential calcium interference. Furthermore, we advocate for the continuous monitoring of calcium correction factors during each sample irradiation. When analyzing extraterrestrial samples, the optical grade CaF₂ crystals should be positioned adjacent to the samples. As a standard product, optical grade CaF₂ crystals are readily accessible to ⁴⁰Ar/³⁹Ar laboratories worldwide.