Your search keyword '"O. V. Petrushkin"' showing total 3 results

1. On the volatility of nihonium (Nh, Z = 113)

Author

I. V. Shirokovsky, Maksim V. Shumeiko, Grigory K. Vostokin, Y. A. Popov, F. S. Abdullin, Yury Tsyganov, R. N. Sagaidak, A. V. Sabelnikov, A. A. Voinov, Robert Eichler, Sergey N. Dmitriev, Patrick Steinegger, O. V. Petrushkin, Vyacheslav Ya. Lebedev, Viktor I. Chepigin, Yury V. Albin, A. N. Polyakov, G. A. Bozhikov, Alexander Sh. Madumarov, A. V. Yeremin, V. K. Utyonkov, O. N. Malyshev, Gennadii Ya. Starodub, and N. V. Aksenov

Subjects

Physics, Nuclear and High Energy Physics, Isotope, Hadron, Analytical chemistry, 010402 general chemistry, 01 natural sciences, Recoil separator, 0104 chemical sciences, Chromatographic separation, Adsorption, 0103 physical sciences, Nuclear fusion, Density functional theory, Atomic physics, Nuclear Experiment, 010306 general physics, Volatility (chemistry)

Abstract

Gas-phase chromatography studies of nihonium (Nh, $Z=113$ ) were carried out at the one-atom-at-a-time level. For the production of nihonium, the heavy-ion-induced nuclear fusion reaction of 48Ca with 243Am was used. This leads to isotopes 284,285Nh, as the direct descendants of the $\alpha$ -decaying precursors 288,289Mc. Combining the Dubna Gas-Filled Recoil Separator with gas-phase chromatographic separation, the experiment was sensitive to elemental nihonium and its adsorption behavior on Teflon, theoretically predicted by modern relativistic density functional theory. The non-observation of any decays of Nh after the chemical separation indicates a larger than expected retention of elemental Nh on a Teflon surface.

Published

2017

2. Preparation and high intensity heavy ion irradiation tests of intermetallic Am-243/Pd targets

Author

G. A. Bozhikov, Grigory K. Vostokin, O. V. Petrushkin, I. Usoltsev, V. Ya. Lebedev, S. N. Dmitriev, A. V. Sabelnikov, A. I. Svirikhin, N. V. Aksenov, Andreas Türler, V. I. Chepigin, D. Piguet, Yu. V. Albin, G. Ya. Starodub, A. V. Yeremin, O. N. Malyshev, and Robert Eichler

Subjects

Nuclear reaction, Nuclear and High Energy Physics, Materials science, High intensity, Cyclotron, Radiochemistry, Intermetallic, 010402 general chemistry, 7. Clean energy, 01 natural sciences, 0104 chemical sciences, law.invention, law, 0103 physical sciences, Microscopy, Irradiation, 010306 general physics, Spectroscopy, Electroplating, Instrumentation

Abstract

Previously reported preparation method for Pd-based intermetallic targets (Usoltsev, et al., 2012) [1] has been successfully applied for producing two stationary 243Am/Pd targets. Both targets have been irradiated at the U-400 cyclotron at Flerov Laboratory of Nuclear Reactions Dubna (Russian Federation) using high intensity beams (up to 0.83 μApart) of 48Ca18+. Alpha-particle spectroscopy and light microscopy allowed for a comprehensive characterization of the intermetallic targets before and after irradiation. A natNd/Pd intermetallic target and a solely electroplated 243Am/Ti target were similarly investigated for comparison.

Published

2014

3. Gas phase chemical studies of superheavy elements using the Dubna gas-filled recoil separator - Stopping range determination

Author

S. Hübener, G. A. Bozhikov, David Wittwer, D. A. Shaughnessy, Evgeny E. Tereshatov, M. Wegrzecki, Rugard Dressler, Yu. S. Tsyganov, S. V. Shishkin, Heinz W. Gäggeler, A. N. Polyakov, Roger Henderson, Yu. V. Albin, Kenton J. Moody, O. V. Petrushkin, P. Rasmussen, Robert Eichler, N. J. Stoyer, S. N. Dmitriev, I. V. Shirokovsky, V. Ya. Lebedev, F. Sh. Abdullin, Yu. Ts. Oganessian, Alexey A. Serov, P. A. Wilk, R. N. Sagaidak, Grigory K. Vostokin, A. M. Sukhov, J. M. Kenneally, Yu. V. Lobanov, M. A. Stoyer, V. K. Utyonkov, N. V. Aksenov, and D. Piguet

Subjects

Nuclear and High Energy Physics, Argon, 010308 nuclear & particles physics, chemistry.chemical_element, Kinetic energy, 01 natural sciences, 7. Clean energy, Ion, Nuclear physics, Thermalisation, chemistry, 0103 physical sciences, Nuclear fusion, Nobelium, Decay chain, Atomic physics, 010306 general physics, Nucleon, Instrumentation

Abstract

Currently, gas phase chemistry experiments with heaviest elements are usually performed with the gas-jet technique with the disadvantage that all reaction products are collected in a gas-filled thermalisation chamber adjacent to the target. The incorporation of a physical preseparation device between target and collection chamber opens up the perspective to perform new chemical studies. But this approach requires detailed knowledge of the stopping force (STF) of the heaviest elements in various materials. Measurements of the energy loss of mercury (Hg), radon (Rn), and nobelium (No) in Mylar and argon (Ar) were performed at low kinetic energies of around (40–270) keV per nucleon. The experimentally obtained values were compared with STF calculations of the commonly used program for calculating stopping and ranges of ions in matter (SRIM). Using the obtained data points an extrapolation of the STF up to element 114, eka-lead, in the same stopping media was carried out. These estimations were applied to design and to perform a first chemical experiment with a superheavy element behind a physical preseparator using the nuclear fusion reaction 244Pu(48Ca; 3n)289114. One decay chain assigned to an atom of 285112, the α-decay product of 289114, was observed.

Published

2010