Your search keyword '"Sadia Adachi"' showing total 3 results

1. Chemical Characterization of a Volatile Dubnium Compound, DbOCl3

Author

Katsuyuki Tokoi, Kazuaki Tsukada, Hiroki Inoue, Nadine M. Chiera, Yuta Ito, Ayuna Kashihara, Rugard Dressler, Tomohiro Tomitsuka, Eisuke Watanabe, Kaori Shirai, Masato Asai, Katsuhisa Nishio, Sadia Adachi, Tetsuya Sato, Kentaro Hirose, Hayato Suzuki, Yuichiro Nagame, Robert Eichler, Minoru Sakama, and Hiroyuki Makii

Subjects

Dubnium, Materials science, Transactinides | Hot Paper, Communication, gas chromatography, Group 5 elements, Analytical chemistry, Transactinide element, chemistry.chemical_element, General Chemistry, Atmospheric temperature range, Catalysis, Communications, Characterization (materials science), Gas phase, chemistry, Thermochemistry, thermochemistry, Gas chromatography, dubnium, Volatility (chemistry), transactinides

Abstract

The formation and the chemical characterization of single atoms of dubnium (Db, element 105), in the form of its volatile oxychloride, was investigated using the on‐line gas phase chromatography technique, in the temperature range 350–600 °C. Under the exactly same chemical conditions, comparative studies with the lighter homologues of Group 5 in the Periodic Table clearly indicate the volatility sequence being NbOCl3 > TaOCl3 ≥ DbOCl3. From the obtained experimental results, thermochemical data for DbOCl3 were derived. The present study delivers reliable experimental information for theoretical calculations on chemical properties of transactinides., Dubnium obeys Mendeleev's periodicity. Fifty years after the discovery of this element, its chemical behavior was experimentally revisited. From the gas chromatographic investigation of the volatile oxychloride compound, a trend of decreasing volatility along Group 5 elements was deduced, in agreement with the expectations by the laws established in the Periodic Table.

Published

2021

2. Quantum Simulation Verifies the Stability of an 18-Coordinated Actinium-Helium Complex

Author

Eiki Ozama, Motoyuki Shiga, Toshiyuki Takayanagi, and Sadia Adachi

Subjects

Chemistry, Coordination number, Organic Chemistry, chemistry.chemical_element, Quantum simulator, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Molecular physics, Catalysis, 0104 chemical sciences, Actinium, Solvation shell, Ab initio quantum chemistry methods, Path integral molecular dynamics, Physics::Atomic and Molecular Clusters, Cluster (physics), Physics::Atomic Physics, 0210 nano-technology, Helium

Abstract

Structures of a trivalent actinium cation in helium clusters (Ac3+ ⋅Hen ) have been studied by quantum path integral molecular dynamics simulations with different cluster sizes, n=18-200. The nuclear quantum effect of helium atoms plays an important role in the vibrational amplitude of the Ac3+ -He complex at low temperatures (1-3 K) at which the complex is stable. We found that the coordination number of helium atoms comprising the first solvation shell can be as high as eighteen. In this case, the helium atoms are arranged in D4d symmetry. The Ac3+ -He18 complex becomes more rigid as the cluster increases in size, which implies that it becomes more stable. The simulation results are based on an accurate description of the Ac3+ -He interaction using relativistic ab initio calculations.

Published

2018

3. Inside Back Cover: Chemical Characterization of a Volatile Dubnium Compound, DbOCl 3 (Angew. Chem. Int. Ed. 33/2021)

Author

Tetsuya Sato, Kazuaki Tsukada, Ayuna Kashihara, Katsuyuki Tokoi, Hayato Suzuki, Robert Eichler, Kaori Shirai, Yuta Ito, Katsuhisa Nishio, Tomohiro Tomitsuka, Eisuke Watanabe, Hiroyuki Makii, Sadia Adachi, Masato Asai, Kentaro Hirose, Nadine M. Chiera, Hiroki Inoue, Rugard Dressler, Yuichiro Nagame, and Minoru Sakama

Subjects

Dubnium, Chemistry, INT, Thermochemistry, Analytical chemistry, chemistry.chemical_element, Transactinide element, Cover (algebra), General Chemistry, Gas chromatography, Catalysis, Characterization (materials science)

Published

2021