6533b7defe1ef96bd1276751
RESEARCH PRODUCT
Decomposition studies of group 6 hexacarbonyl complexes. Part 1: Production and decomposition of Mo(CO)6 and W(CO)6
Alexander YakushevPatrick SteineggerPatrick SteineggerAndreas TürlerAndreas TürlerDaiya KajiK. MorimotoS. YamakiZhiyong QinJ. KanayaMinghui HuangI. UsoltsevI. UsoltsevMirei TakeyamaTetsuya SatoY. NagameK. TanakaHiromitsu HabaH. BrandN. KurzTakayuki SumitaMatthias SchädelKosuke MoritaKazuaki TsukadaMasashi MurakamiJ. KrierEgon JägerSunao MiyashitaSunao MiyashitaAtsushi ToyoshimaJ. V. KratzY. KaneyaF. FangliBirgit KindlerY. KudouA. Di NittoRobert EichlerRobert EichlerJadambaa KhuyagbaatarYuezhao WangNorbert WiehlJulia EvenYasuo WakabayashiBettina LommelW. HartmannJ. SteinerM. AsaiHeino NitscheHeino NitscheCh. E. DüllmannCh. E. DüllmannKazuhiro Ooesubject
Inorganic chemistryMetal carbonyl02 engineering and technology010402 general chemistry01 natural sciences7. Clean energythermal stability540 ChemistryseaborgiumThermal stabilityNuclideGas compositionPhysical and Theoretical Chemistrycarbonyl complexegroup 6ChemistrytransactinideTransition metals021001 nanoscience & nanotechnologyDecompositionBond-dissociation energy0104 chemical sciencesVolumetric flow rateYield (chemistry)570 Life sciences; biologyPhysical chemistry0210 nano-technologydescription
Abstract Chemical studies of superheavy elements require fast and efficient techniques, due to short half-lives and low production rates of the investigated nuclides. Here, we advocate for using a tubular flow reactor for assessing the thermal stability of the Sg carbonyl complex – Sg(CO)6. The experimental setup was tested with Mo and W carbonyl complexes, as their properties are established and supported by theoretical predictions. The suggested approach proved to be effective in discriminating between the thermal stabilities of Mo(CO)6 and W(CO)6. Therefore, an experimental verification of the predicted Sg–CO bond dissociation energy seems to be feasible by applying this technique. By investigating the effect of 104,105Mo beta-decay on the formation of 104,105Tc carbonyl complex, we estimated the lower reaction time limit for the metal carbonyl synthesis in the gas phase to be more than 100 ms. We examined further the influence of the wall material of the recoil chamber, the carrier gas composition, the gas flow rate, and the pressure on the production yield of 104Mo(CO)6, so that the future stability tests with Sg(CO)6 can be optimized accordingly.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2015-11-06 |