Patterson Melissa J, Lightstone James M, White Michael G
Department of Chemistry, Stony Brook University, Stony Brook, New York 11974, USA.
J Phys Chem A. 2008 Nov 27;112(47):12011-21. doi: 10.1021/jp807318c.
A combination of experiment and density functional theory was used to investigate the energetics of CO adsorption onto several small M(x)S(y)(+) (M = Mo, W; x/y = 2/6, 3/7, 5/7, 6/8) clusters as a probe of their atomic and electronic structure. Experimentally, tandem mass spectrometry was used to measure the relative yields of M(x)S(y)(+)(CO)(n) cluster adducts formed by collisions between a beam of mass-selected M(x)S(y)(+) cluster ions and CO molecules in a high-pressure collision cell (hexapole ion guide). The most probable M(x)S(y)(+)(CO)(n) adducts observed are those with n < or = x, that is, only one CO molecule bound to each metal site. The notable exception is the M(5)S(7)(+) cluster, for which the n = 6 adduct is found to have nearly the same intensity as the n = x = 5 adduct. Density functional calculations were used to search for the lowest energy structures of the bare M(x)S(y)(+) clusters and to obtain their relative stability for sequential CO binding. The calculated trends in CO binding energies were then compared to the experimental adduct distributions for assigning the ground-state structures. In this way, it was possible to distinguish between two nearly isoenergetic ground-state isomers for the M(2)S(6)(+) and M(3)S(7)(+) clusters, as only one isomer gave a calculated CO stabilization energy trend that was consistent with the experimental data. Similar comparisons of predicted and observed CO adsorption trends also provide evidence for assigning the ground-state structures of the M(5)S(7)(+) and M(6)S(8)(+) clusters. The latter contain metallic cores with most of the sulfur atoms bonded along the edges or in the faces of the metal core structure. The n = 6 and 7 adducts of M(5)S(7)(+) are predicted to be more stable than the n = x = 5 adduct, but only the n = 6 adduct is observed experimentally. The DFT calculations show that the n = 7 adduct undergoes internal bond breaking whereas the n = 6 framework is stable, albeit highly distorted. For the M(6)S(8)(+) cluster, the calculations predict that the two lowest energy isomers can bind more than six CO molecules without fragmentation; however, the apparent binding energy drops significantly for adducts with n > 6. In general, the ability of these small M(x)S(y)(+) clusters to bind more CO molecules than the number of metal atoms is a balance between the gain in CO adsorption energy versus the strain introduced into the cluster structure caused by CO crowding, the consequences of which can be fragmentation of the M(x)S(y)(+)(CO)(n) cluster adduct (n > x).
采用实验与密度泛函理论相结合的方法,研究了CO吸附在几个小的M(x)S(y)(+)(M = Mo、W;x/y = 2/6、3/7、5/7、6/8)团簇上的能量变化,以此作为其原子结构和电子结构的探针。实验上,利用串联质谱法测量在高压碰撞池(六极离子导向器)中,经质量选择的M(x)S(y)(+)团簇离子束与CO分子碰撞形成的M(x)S(y)(+)(CO)(n)团簇加合物的相对产率。观察到的最可能的M(x)S(y)(+)(CO)(n)加合物是那些n ≤ x的加合物,即每个金属位点仅结合一个CO分子。显著的例外是M(5)S(7)(+)团簇,其n = 6的加合物强度与n = x = 5的加合物几乎相同。密度泛函计算用于寻找裸M(x)S(y)(+)团簇的最低能量结构,并获得其连续CO结合的相对稳定性。然后将计算得到的CO结合能趋势与实验加合物分布进行比较,以确定基态结构。通过这种方式,能够区分M(2)S(6)(+)和M(3)S(7)(+)团簇的两种近乎等能量的基态异构体,因为只有一种异构体给出的计算CO稳定能趋势与实验数据一致。对预测和观察到的CO吸附趋势进行类似比较,也为确定M(5)S(7)(+)和M(6)S(8)(+)团簇的基态结构提供了证据。后者包含金属核,大部分硫原子沿金属核结构的边缘或面键合。预计M(5)S(7)(+)的n = 6和7加合物比n = x = 5的加合物更稳定,但实验上仅观察到n = 6的加合物。DFT计算表明,n = 7的加合物会发生内部键断裂,而n = 6的结构框架是稳定的,尽管高度扭曲。对于M(6)S(8)(+)团簇,计算预测两个最低能量异构体可以结合超过六个CO分子而不发生碎片化;然而,对于n > 6的加合物,表观结合能会显著下降。一般来说,这些小的M(x)S(y)(+)团簇结合比金属原子数更多CO分子的能力,是CO吸附能增加与CO拥挤导致团簇结构引入应变之间的平衡,其结果可能是M(x)S(y)(+)(CO)(n)团簇加合物(n > x)的碎片化。
