Transient Radiation-Induced Berkelium(III) and Californium(III) Redox Chemistry in Aqueous Solution

Despite the significant impact of radiation-induced redox reactions on the accessibility and lifetimes of actinide oxidation states, fundamental knowledge of aqueous actinide metal ion radiation chemistry is limited, especially for the late actinides. A quantitative understanding of these intrinsic radiation-induced processes is essential for investigating the fundamental properties of these actinides. We present here a picosecond electron pulse reaction kinetics study into the radiation-induced redox chemistry of trivalent berkelium (Bk(III)) and californium (Cf(III)) ions in acidic aqueous solutions at ambient temperature. New and first-of-a-kind, second order rate coefficients are reported for the transient radical-induced reduction of Bk(III) and Cf(III) by the hydrated electron (e(aq)(-)) and hydrogen atom (H-center dot), demonstrating a significant reactivity (up to 1011 M-1 s(-1)) indicative of a preference of these metals to adopt divalent states. Additionally, we report the first-ever second order rate coefficients for the transient radical-induced oxidation of these elements by a reaction with hydroxyl ((OH)-O-center dot) and nitrate (NO3 center dot) radicals, which also exhibited fast reactivity (ca. 10(8) M-1 s(-1)). Transient Cf(II), Cf(IV), and Bk(IV) absorption spectra are also reported. Overall, the presented data highlight the existence of rich, complex, intrinsic late actinide radiation-induced redox chemistry that has the potential to influence the findings of other areas of actinide science.