• Title/Summary/Keyword: Ion-Molecule Association

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Oxygen Ring Formation Reaction of Mono-Oxo-Bridged Binuclear Molybdenum(V) Complex (II). Reaction of $[Mo_2O_3(Phen)_2(NCS)_4]$ with Solvent Water in Water + Co-Solvent Mixtures (한개의 산소다리를 가진 몰리브덴(V) 착물의 산소고리화 반응 (II). 2성분 혼합용매에서 용매물과 $[Mo_2O_3(Phen)_2(NCS)_4]$의 반응)

  • Sang-Oh Oh;Huee-Young Seok
    • Journal of the Korean Chemical Society
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    • v.32 no.3
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    • pp.203-210
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    • 1988
  • Mono-oxo-bridged binuclear molybdenum(V) complex, $[Mo_2O_3(Phen)_2(NCS)_4]$ produces di-oxo-bridged binuclear molybdenum(V) complex, $[Mo_2O_4(Phen)_2(NCS)_2]$ in water + co-solvent, where the co-solvent are acetone, acetonitrile and N,N-dimethylformamide. The rate of conversion of $[Mo_2O_3(Phen)_2(NCS)_4]\;into\;[Mo_2O_4(Phen)_2(NCS)_2]$ has been measured by spectrophotometric method. Temperature was $10^{\circ}C$ to $40^{\circ}C$ and pressure was varied up to 1500 bar. The rate constants are increased with increasing water mole fraction and decreased with increasing concentration of hydrogen ion. The order of oxygen ring formation reaction rate in various cosolvent is as follows, ACT > AN > DMF which is agreed with solvent dielectric constants. The observed negative activation entropy ($[\Delta}S^{\neq}$), activation volume($[\Delta}V^{\neq}$) and activation compressibility coefficient(${\Delta}{\beta}^{\neq}$) values show that the solvent water molecule is strongly attracted to the complex at transition state. From these results, the oxygen ring formation reaction of $[Mo_2O_3(Phen)_2(NCS)_4]$ is believed association mechanism.

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