Unravelling relativistic effects in the heaviest actinide element
The first-time measurement of the first ionization potential of lawrencium (element 103)
Since the introduction of the "actinide concept" as the most dramatic modern revision of the Periodic Table of the Elements by Glenn T. Seaborg in the 1940s, the element with atomic number 103, lawrencium (Lr), played a crucial role as the last element in the actinide series. This special position turned out to set this element into the focus of questions on the influence of relativistic effects and the determination of properties confirming its position as the last actinide element. Consequently, the quest for data on chemical and physical properties of Lr was driving experimental and theoretical studies. Two aspects most frequently addressed concerned its ground state electronic configuration and the value of its first ionization potential. As the last element in the actinide series, and similar to lutetium (Lu) as the last element in the lanthanide series, it was expected that Lr has a very low first ionization potential that is strongly influenced by relativistic effects.
However, Lr is only accessible atom-at-a-time in syntheses at heavy-ion accelerators, and only short-lived isotopes are known. Therefore, experimental investigations on Lr are very rare and have so far been limited to a few studies of some basic chemical properties. In their new work, for which the international research collaboration exploited a novel combination and advancement of methods and techniques, the researchers report on the first and accurate measurement of the first ionization potential of Lr. For the experiment, the Institute of Nuclear Chemistry at Johannes Gutenberg University Mainz purified and prepared the exotic target material californium (element 98). The material was converted into a target in Japan and then exposed to a beam of boron ions (element 5). The experiment was supplemented by theoretical calculations undertaken by scientists at the Helmholtz Institute Mainz (HIM) and at Tel Aviv University of Israel using the most up-to-date quantum chemical methods to quantify the ionization energy. The very good agreement between calculated and experimental result validates the quantum chemical calculations. The experimental technique opens up new perspectives for similar studies of yet more exotic, superheavy elements.
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