PMID- 16848601
OWN - NLM
STAT- PubMed-not-MEDLINE
DCOM- 20070727
LR  - 20060719
IS  - 0021-9606 (Print)
IS  - 0021-9606 (Linking)
VI  - 125
IP  - 2
DP  - 2006 Jul 14
TI  - Seven-dimensional microcanonical treatment of hydrogen dissociation dynamics on 
      Cu(111): clarifying the essential role of surface phonons.
PG  - 24704
AB  - A simple picture of the hydrogen dissociation/associative desorption dynamics on 
      Cu(111) emerges from a two-parameter, full dimensionality microcanonical 
      unimolecular rate theory (MURT) model of the gas-surface reactivity. Vibrational 
      frequencies for the reactive transition state were taken from density functional 
      theory calculations of a six-dimensional potential energy surface [Hammer et al., 
      Phys. Rev. Lett. 73, 1400 (1994)]. The two remaining parameters required by the 
      MURT were fixed by simulation of experiments. These parameters are the 
      dissociation threshold energy, E(0)=79 kJmol, and the number of surface 
      oscillators involved in the localized H(2)Cu(111) collision complex, s=1. The 
      two-parameter MURT quantitatively predicts much of the varied behavior observed 
      for the H(2) and D(2)Cu(111) reactive systems, including the 
      temperature-dependent associative desorption angular distributions, mean 
      translational energies of the associatively desorbing hydrogen as a function of 
      rovibrational eigenstate, etc. The divergence of the statistical theory's 
      predictions from experimental results at low rotational quantum numbers, J < or 
      approximately 5, suggests that either (i) rotational steering is important to the 
      dissociation dynamics at low J, an effect that washes out at high J, or (ii) 
      molecular rotation is approximately a spectator degree of freedom to the 
      dissociation dynamics for these low J states, the states that dominate the 
      thermal reactivity. Surface vibrations are predicted to provide approximately 30% 
      of the energy required to surmount the activation barrier to H(2) dissociation 
      under thermal equilibrium conditions. The MURT with s=1 is used to analytically 
      confirm the experimental finding that partial differential "E(a)(T(s))" partial 
      differential E(t)= -1 for eigenstate-resolved dissociative sticking at 
      translational energies E(t)<E(0)-E(v)-E(r). Explicit treatment of the surface 
      motion (i.e., surface not frozen at T(s)=0 K) is a relatively novel aspect of the 
      MURT theoretical approach.
FAU - Abbott, H L
AU  - Abbott HL
AD  - Department of Chemistry, University of Virginia, Charlottesville, VA 22904-4319, 
      USA.
FAU - Harrison, I
AU  - Harrison I
LA  - eng
PT  - Journal Article
PL  - United States
TA  - J Chem Phys
JT  - The Journal of chemical physics
JID - 0375360
EDAT- 2006/07/20 09:00
MHDA- 2006/07/20 09:01
CRDT- 2006/07/20 09:00
PHST- 2006/07/20 09:00 [pubmed]
PHST- 2006/07/20 09:01 [medline]
PHST- 2006/07/20 09:00 [entrez]
AID - 10.1063/1.2208362 [doi]
PST - ppublish
SO  - J Chem Phys. 2006 Jul 14;125(2):24704. doi: 10.1063/1.2208362.