Departamento de Física de la Materia Condensada, Universidad Autónoma de Madrid, 28049 Madrid, Spain.
Phys Chem Chem Phys. 2011 May 14;13(18):8583-97. doi: 10.1039/c0cp02425b. Epub 2011 Apr 12.
We present a combined experimental and theoretical study of the diffraction of H(2) from Ru(0001) in the incident energy range 78-150 meV, and a theoretical study of dissociative chemisorption of H(2) in the same system. Pronounced out-of-plane diffraction was observed in the whole energy range studied. The energy dependence of the elastic diffraction intensities was measured along the two main symmetry directions for a fixed parallel translational energy. The data were compared with quantum dynamics calculations performed by using DFT-based, six-dimensional potential energy surfaces calculated with both the PW91 and RPBE functionals, as well as with a functional obtained from a weighted average of both (the MIX functional, which was earlier shown to perform quite well for H(2) + Cu(111)). Our results show that the PW91 functional describes the H(2) diffraction intensities more accurately than the RPBE and the MIX functionals, although the absolute values of these intensities are overestimated in the calculations. For the reaction probabilities a preference for one or the other functional cannot be given over the entire energy range probed by the sticking experiments. The PW91 functional yields too high reaction probabilities over the entire investigated energy range, but is better than RPBE at low collision energies (<0.1 eV). The RPBE functional gives too low reaction probabilities at low energy and somewhat too high reaction probabilities at high energy, but agrees better with experiment than PW91 for energies >0.1 eV. The results suggest that, in order to get a better description of both H(2) diffraction and dissociative chemisorption for this system, a specific reaction parameter functional for H(2) + Ru(0001) is needed that is a weighted average of functionals other than PW91 and RPBE. We speculate that differences between the H(2) + Ru(0001) system (early and low reaction barrier) and H(2) + Cu(111) (late and high reaction barrier) may well lead to fundamentally different specific reaction parameter functionals, and that including a reasonable accurate description of the van der Waals interaction might be important for H(2) + Ru(0001) which has barriers localised far away from the surface. Based on our results we advocate new, systematic combined theoretical and experimental studies of H(2) interacting with transition metals in early and late barrier systems, with the aim of determining whether specific reaction parameter functionals for these systems might differ in a systematic way.
我们呈现了一项关于 H(2) 在 Ru(0001)上的散射的实验和理论研究,其入射能量范围为 78-150 meV,以及对 H(2)在同一体系中进行的离解化学吸附的理论研究。在整个研究的能量范围内,观察到了明显的非平面散射。我们沿着两个主要的对称方向测量了弹性衍射强度随能量的变化,对于固定的平行平移能量。数据与使用基于 DFT 的六维势能面进行的量子动力学计算进行了比较,这些势能面是使用 PW91 和 RPBE 泛函以及通过对两者进行加权平均得到的函数(MIX 函数,该函数之前已被证明对于 H(2) + Cu(111)非常有效)。我们的结果表明,PW91 泛函比 RPBE 和 MIX 泛函更准确地描述了 H(2)的衍射强度,尽管这些强度的绝对值在计算中被高估了。对于反应概率,在整个被粘性实验探测到的能量范围内,不能给出对一个或另一个泛函的偏好。PW91 泛函在整个研究的能量范围内给出了过高的反应概率,但在低碰撞能量(<0.1 eV)下比 RPBE 更好。RPBE 泛函在低能量时给出的反应概率过低,在高能量时给出的反应概率过高,但对于能量>0.1 eV 的情况,它比 PW91 更符合实验结果。结果表明,为了更好地描述该体系中的 H(2)衍射和离解化学吸附,需要一个特定的用于 H(2) + Ru(0001)的反应参数泛函,它是 PW91 和 RPBE 以外的泛函的加权平均值。我们推测,H(2) + Ru(0001)体系(早期和低反应势垒)和 H(2) + Cu(111)体系(晚期和高反应势垒)之间的差异很可能导致特定的反应参数泛函具有根本的不同,并且对于 H(2) + Ru(0001),包括对范德华相互作用的合理准确描述可能很重要,因为其势垒位于远离表面的地方。基于我们的结果,我们提倡对 H(2)与过渡金属相互作用的早期和晚期势垒体系进行新的、系统的理论和实验联合研究,目的是确定这些体系的特定反应参数泛函是否可能以系统的方式存在差异。
