Application of a novel gas phase synthesis approach to carbonyl complexes of accelerator-produced 5d transition metals
Author:
Götz Michael123, Yakushev Alexander2, Götz Stefan123, Di Nitto Antonio4, Düllmann Christoph E.123, Asai Masato5, Kindler Birgit2, Krier Jörg2, Lommel Bettina2, Nagame Yuichiro5, Sato Tetsuya K.5, Suzuki Hayato56, Tomitsuka Tomohiro5, Tokoi Katsuyuki57, Toyoshima Atsushi57, Tsukada Kazuaki5
Affiliation:
1. Department of Chemistry – TRIGA Site , Johannes Gutenberg University Mainz , 55128 Mainz , Germany 2. GSI Helmholtz Centre for Heavy Ion Research , 64291 Darmstadt , Germany 3. Helmholtz Institute Mainz , 55099 Mainz , Germany 4. Physics Department Ettore Pancini , University of Naples Federico II , 80126 Naples , Italy 5. Japan Atomic Energy Agency , Tokai-mura , Ibaraki 319-1111 , Japan 6. Ibaraki University , Mito , Ibaraki 310-8512 , Japan 7. Osaka University , Suita , Osaka 565-0871 , Japan
Abstract
Abstract
In 2014 the first synthesis of a transactinide carbonyl complex – seaborgium hexacarbonyl – was reported. This was achieved in gas-phase chemical experiments in a beam-free environment behind the recoil separator GARIS. Extending this work to heavier elements requires more efficient techniques to synthesize carbonyl complexes as production rates of transactinide elements drop with increasing atomic number. A novel approach was thus conceived, which retains the benefit of a beam-free environment but avoids the physical preseparation step. The latter reduces the yields for products of asymmetric reactions such as those used for the synthesis of suitable isotopes of Sg, Bh, Hs and Mt. For this a series of experiments with accelerator-produced radioisotopes of the lighter homologues W, Re and Os was carried out at the tandem accelerator of JAEA Tokai, Japan. A newly developed double-chamber system, which allows for a decoupled recoil ion thermalization and chemical complex formation, was used, which avoids the low-efficiency physical preseparation step. Here, we demonstrate the feasibility of this newly developed method using accelerator-produced short-lived radioisotopes of the 5d homologues of the early transactinides.
Publisher
Walter de Gruyter GmbH
Subject
Physical and Theoretical Chemistry
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