Assessment of the Second-Ionization Potential of Lawrencium: Investigating the End of the Actinide Series with a One-Atom-at-a-Time Gas-Phase Ion Chemistry Technique

Experiments were performed at the Lawrence Berkeley National Laboratory 88-Inch Cyclotron facility to investigate the electron-transfer reduction reaction of dipositive Lr (Z = 103) with O-2 gas. Ions of Lr-255 were produced in the fusion-evaporation reaction Bi-209(Ca-48,2n) Lr-255 and were studied with a novel gas-phase ion chemistry technique. The produced Lr-255(2+) ions were trapped and O-2 gas was introduced, such that the charge-exchange reaction to reduce Lr-255(2+) to Lr-255(1+) was observed and the reaction rate constant was determined to be k = 1.5(7) x 10(-10) cm(3)/mol/s. The observation that this reaction proceeds establishes the lower limit on the second ionization potential of Lr to be 13.3(3) eV. This gives further support that the actinide series terminates with Lr. Additionally, this result can be used to better interpret the situation concerning the placement of Lu and Lr on the periodic table within the current framework of the actinide hypothesis. The success of this experimental approach now identifies unique opportunities for future gas-phase reaction studies on actinide and super heavy elements.

Automated summary

The experiment investigated the electron-transfer reduction reaction of dipositive Lr with O-2 gas, determining the lower limit of Lr's second ionization potential and supporting the termination of the actinide series with Lr. This result can also help clarify the placement of Lu and Lr on the periodic table within the current framework of the actinide hypothesis, opening up unique opportunities for future gas-phase reaction studies on actinide and super heavy elements.