Dynamics and Kinetics of Methanol-Graphite Interactions at Low Surface Coverage
Artikel i vetenskaplig tidskrift, 2019

The processes of molecular clustering, condensation, nucleation, and growth of bulk materials on surfaces, represent a spectrum of vapor-surface interactions that are important to a range of physical phenomena. Here, we describe studies of the initial stages of methanol condensation on graphite, which is a simple model system where gas–surface interactions can be described in detail using combined experimental and theoretical methods. Experimental molecular beam methods and computational molecular dynamics simulations are used to investigate collision dynamics and surface accommodation of methanol molecules and clusters at temperatures from 160 K to 240 K. Both single molecules and methanol clusters efficiently trap on graphite, and even in rarified systems methanol-methanol interactions quickly become important. A kinetic model is developed to simulate the observed behavior, including the residence time of trapped molecules and the quantified Arrhenius kinetics. Trapped molecules are concluded to rapidly diffuse on the surface to find and/or form clusters already at surface coverages below 10−6 monolayers. Conversely, clusters that undergo surface collisions fragment and subsequently lose more loosely bound molecules. Thus, the surface mediates molecular collisions in a manner that minimizes the importance of initial cluster size, but highlights a strong sensitivity to surface diffusion and intermolecular interactions between the hydrogen bonded molecules.

molecular beam

methanol

condensation

nucleation

graphite

Författare

Xiangrui Kong

Göteborgs universitet

Erik S Thomson

Göteborgs universitet

Nikola Markovic

Chalmers, Kemi och kemiteknik, Kemi och biokemi

Jan B. C. Pettersson

Göteborgs universitet

ChemPhysChem

1439-4235 (ISSN) 1439-7641 (eISSN)

Vol. 20 17 2171-2178

Ämneskategorier

Fysikalisk kemi

Atom- och molekylfysik och optik

Teoretisk kemi

DOI

10.1002/cphc.201900457

Mer information

Senast uppdaterat

2019-10-29