Your search keyword '"Masato Asai"' showing total 2 results

1. Study of fission using multi-nucleon transfer reactions.

Author

Shouya Tanaka, Yoshihiro Aritomo, Satoshi Chiba, Yuichiro Nagame, Sato, Tetsuya K., Atsushi Toyoshima, Masato Asai, Riccardo Orlandi, Hiroyuki Makii, Vermeulen, Mark, Kentaro Hirose, Kazuaki Tsukada, Katsuhisa Nishio, Tsutomu Ohtsuki, Igor Tsekhanovich, Petrache, Costel M., and Andreyev, Andrei

Subjects

NUCLEON-nucleon scattering, NUCLEAR fission, NUCLIDES, ENERGY dissipation, EXCITATION energy (In situ microanalysis)

Abstract

Multi-nucleon transfer channels of the reactions of 18O+232Th, 18O+238U, 18O+248Cm were used to measure fission-fragment mass distribution for various nuclides and their excitation energy dependence. Predominantly asymmetric fission is observed at low excitation energies for all the studied cases, with an increase of the symmetric fission towards high excitation energies. Experimental data are compared with predictions of the fluctuation-dissipation model, where effects of multi-chance fission (neutron evaporation prior to fission) was introduced. It was shown that a reliable understanding of the observed fission fragment mass distributions can be obtained only invoking multi-chance fissions. [ABSTRACT FROM AUTHOR]

Published

2018

2. First ionization potential of the heaviest actinide lawrencium, element 103.

Author

Sato, Tetsuya K., Masato Asai, Borschevsky, Anastasia, Stora, Thierry, Nozomi Sato, Yusuke Kaneya, Kazuaki Tsukada, Düllmann, Christoph E., Eberhardt, Klaus, Eliav, Ephraim, Shinichi Ichikawa, Uzi Kaldor, Kratz, Jens V., Sunao Miyashita, Yuichiro Nagame, Kazuhiro Ooe, Akihiko Osa, Renisch, Dennis, Runke, Jörg, and Schädel, Matthias

Subjects

IONIZATION (Atomic physics), ATOMIC physics, MOLECULAR physics, ACTINIDE elements, HEAVY elements

Abstract

The first ionization potential (IP1) of element 103, lawrencium (Lr), has been successfully determined for the first time by using a newly developed method based on a surface ionization process. The measured IP1 value is 4.9630.080.07 eV. This value is the smallest among those of actinide elements and is in excellent agreement with the value of 4.963(15) eV predicted by state-of-the-art relativistic calculations also performed in this work. Our results strongly support that the Lr atom has an electronic configuration of [Rn]7s²5f147p¹1/2, which is influenced by strong relativistic effects. The present work provides a reliable benchmark for theoretical calculations and also opens the way for studies on atomic properties of heavy elements with atomic number Z > 100. Moreover, the present achievement has triggered a controversy on the position of lutetium (Lu) and Lr in the Periodic Table of Elements. [ABSTRACT FROM AUTHOR]

Published

2016