The impact of ambient gas molecules (X), NO2, CO2 and SO2 on the structure, stability and decontamination activity of Cs8Nb6O19 polyoxometalate was studied computationally and experimentally. It was found that Cs8Nb6O19 absorbs these molecules more strongly than it adsorbs water and Sarin (GB) and that these interactions hinder nerve agent decontamination. The impacts of diamagnetic CO2 and SO2 molecules on polyoxoniobate Cs8Nb6O19 were fundamentally different from that of NO2 radical. At ambient temperatures, weak coordination of the first NO2 radical to Cs8Nb6O19 conferred partial radical character on the polyoxoniobate and promoted stronger coordination of the second NO2 adsorbent to form a stable diamagnetic Cs8Nb6O19/(NO2)2 species. Moreover, at low temperatures, NO2 radicals formed stable dinitrogen tetraoxide (N2O4) that weakly interacted with Cs8Nb6O19. It was found that both in the absence and presence of ambient gas molecules, GB decontamination by the Cs8Nb6O19 species proceeds via general base hydrolysis involving: (a) the adsorption of water and the nerve agent on Cs8Nb6O19/(X), (b) concerted hydrolysis of a water molecule on a basic oxygen atom of the polyoxoniobate and nucleophilic addition of the nascent OH group to the phosphorus center of Sarin, and (c) rapid reorganization of the formed pentacoordinated-phosphorus intermediate, followed by dissociation of either HF or isopropanol and formation of POM-bound isopropyl methyl phosphonic acid (i-MPA) or methyl phosphonofluoridic acid (MPFA), respectively. The presence of the ambient gas molecules increases the energy of the intermediate stationary points relative to the asymptote of the reactants and slightly increases the hydrolysis barrier. These changes closely correlate with the Cs8Nb6O19–X complexation energy. The most energetically stable intermediates of the GB hydrolysis and decontamination reaction were found to be Cs8Nb6O19/X-MPFA-(i-POH) and Cs8Nb6O19/X-(i-MPA)-HF both in the absence and presence of ambient gas molecules. The high stability of these intermediates is due to, in part, the strong hydrogen bonding between the adsorbates and the protonated [Cs8Nb6O19/X/H]+-core. Desorption of HF or/and (i-POH) and regeneration of the catalyst required deprotonation of the [Cs8Nb6O19/X/H]+-core and protonation of the phosphonic acids i-MPA and MPFA. This catalyst regeneration is shown to be a highly endothermic process, which is the rate-limiting step of the GB hydrolysis and decontamination reaction both in the absence and presence of ambient gas molecules.
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机译:通过计算和实验研究了环境气体分子(X),NO2,CO2和SO2对Cs8Nb6O19多金属氧酸盐的结构,稳定性和去污活性的影响。发现Cs8Nb6O19吸收这些分子的能力比吸收水和Sarin(GB)的吸收强,并且这些相互作用阻碍了神经毒剂的净化。抗磁性的CO2和SO2分子对聚氧杂酸盐Cs8Nb6O19的影响与NO2自由基的影响根本不同。在环境温度下,第一个NO2自由基与Cs 8 Nb 6 O 19 的弱配位赋予聚氧杂酸盐部分偏基特征,并促进了更强的配位NO 2 吸附剂形成稳定的抗磁性Cs 8 Nb 6 O 19 /(NO 2 ) 2 物种。此外,在低温下,NO 2 自由基形成稳定的四氧化二氮(N 2 O 4 ),与Cs 8 < / sub> Nb 6 O 19 。发现在不存在和存在环境气体分子的情况下,Cs 8 Nb 6 O 19 物种对GB的去污都是通过常规方式进行的。碱水解包括:(a)水和神经毒剂在Cs 8 Nb 6 O 19 /(X)上的吸附,(b )在多氧杂酸酯的碱性氧原子上协同水解水分子,并将新生的OH基团亲核加成至Sarin的磷中心,并且(c)形成的五配位磷中间体迅速重组,然后离解任何HF或异丙醇,并形成POM结合的异丙基甲基膦酸(i-MPA)或甲基膦酰氟酸(MPFA)。周围气体分子的存在相对于反应物的渐近线增加了中间固定点的能量,并略微增加了水解屏障。这些变化与Cs 8 Nb 6 O 19 -X络合能密切相关。 GB水解和去污反应中能量最稳定的中间体为Cs 8 Nb 6 O 19 / X-MPFA-(i -POH)和Cs 8 Nb 6 O 19 / X-(i-MPA)-HF在不存在和存在环境气体的情况下分子。这些中间体的高稳定性部分是由于被吸附物与质子化的[Cs 8 Nb 6 O 19 / X / H] + -核心。 HF或/和(i-POH)的解吸和催化剂的再生需要[Cs 8 Nb 6 O 19 / X的质子化/ H] + -核和膦酸i-MPA和MPFA的质子化。该催化剂的再生显示为高度吸热的过程,这是在不存在和存在环境气体分子的情况下GB水解和去污反应的限速步骤。
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