Effect of Surface Modes on the Six-Dimensional Molecule鈥揝urface Scattering Dynamics of H2鈥揅u(100) and D2鈥揅u(111) Systems
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- 作者:Tapas Sahoo ; Subhankar Sardar ; Padmabati Mondal ; Biplab Sarkar ; Satrajit Adhikari
- 刊名:Journal of Physical Chemistry A
- 出版年:2011
- 出版时间:June 2, 2011
- 年:2011
- 卷:115
- 期:21
- 页码:5256-5273
- 全文大小:1462K
- 年卷期:v.115,no.21(June 2, 2011)
- ISSN:1520-5215
文摘
We include the phonon modes originating from the three layers of Cu(100)/Cu(111) surface atoms on the dynamics of molecular [H2(v,j)/D2(v,j)] degrees of freedom (DOFs) through a mean field approach, where the surface temperature is incorporated into the effective Hamiltonian (potential) either by considering Boltzmann probability (BP) or by including the Bose鈥揈instein probability (BEP) factor for the initial state distribution of the surface modes. The formulation of effective potential has been carried out by invoking the expression of transition probabilities for phonon modes known from the 鈥渟tochastic鈥?treatment of linearly forced harmonic oscillator (LFHO). We perform four-dimensional (4D2D) as well as six-dimensional (6D) quantum dynamics on a parametrically time and temperature-dependent effective Hamiltonian to calculate elastic/inelastic scattering cross-section of the scattered molecule for the H2(v,j)鈥揅u(100) system, and dissociative chemisorption鈥損hysisorption for both H2(v,j)鈥揅u(100) and D2(v,j)鈥揅u(111) systems. Calculated sticking probabilities by either 4D2D or 6D quantum dynamics on an effective potential constructed by using BP factor for the initial state distribution of the phonon modes could not show any surface temperature dependence. In the BEP case, (a) both 4D2D and 6D quantum dynamics demonstrate that the phonon modes of the Cu(100) surface affect the state-to-state transition probabilities of the scattered H2 molecule substantially, and (b) the sticking probabilities due to the collision of H2 on Cu(100) and D2 on Cu(111) surfaces show noticeable and substantial change, respectively, as function of surface temperature only when the quantum dynamics of all six molecular DOFs are treated in a fully correlated manner (6D).