Our research is focussed upon the application of first-principles theory and ultra-high-vacuum single-crystal experiments to problems in surface chemistry and catalysis. We make use of fibre-optic low-energy electron diffraction (FO-LEED) to obtain structural information, reflection absorption infra-red spectroscopy (RAIRS) to obtain vibrational information, single-crystal adsorption calorimetry (SCAC) to obtain energetic information, supersonic molecular beams (SMB) to obtain kinetic information, and low- temperature scanning tunnelling microscopy (LT-STM) to obtain morphological, topographic and electronic information about surfaces and the molecules that adsorb, diffuse and react upon them. Density functional theory (DFT) provides a framework within which to calculate comparable data, which aids in the interpretation of our experimental work.
Our work is concentrated within four main research themes: . Complex interadsorbate interactions . Nanoscale surface phenomena . Chiral surface systems . Tuning reactivity and catalysis
Individual research projects are chosen to reflect these themes, lending coherence to a diverse range of topical studies. Thus, by way of example, our work on the adsorption of alanine on Cu{531} addresses issues relating to the formation of complex hydrogen-bonded adsorbate networks, whilst also shedding light on the interaction of chiral molecules with an intrinsically chiral metal surface; moreover, certain adsorbates can cause this unstable surface to break up into nanoscale facets, whose catalytic properties will differ markedly from those of the notionally ideal surface. Tackling these interlinked aspects of surface science requires a flexible approach, making use of multiple experimental techniques complemented by a rigorously benchmarked theoretical methodology.
General
When adding an unreactive metal enhances catalytic activity: NOx decomposition over silver-rhodium bimetallic surfaces
OR Inderwildi, SJ Jenkins, DA King - Surface Science (
2007)
601, L103
(DOI:
10.1016/j.susc.2007.06.031)
Surface states and surface stability in half-metallic systems: the cases of zinc-blende-structure MnSb {111}A, {111}B and {001}
S Mollet, SJ Jenkins - Journal of Physics: Condensed Matter (
2007)
19, 315214
(DOI:
10.1088/0953-8984/19/31/315214)
Lifting of Ir{100} reconstruction by CO adsorption: An ab initio study
P Ghosh, S Narasimhan, SJ Jenkins, DA King - The Journal of Chemical Physics (
2007)
126, 244701
(DOI:
10.1063/1.2741540)
An unexpected pathway for the catalytic oxidation of methylidyne on Rh{111} as a route to syngas.
OR Inderwildi, SJ Jenkins, DA King - Journal of the American Chemical Society (
2007)
129, 1751
(DOI:
10.1021/ja067722w)
Theory of C2Hx species on Pt{110} (1x2): Reaction pathways for dehydrogenation
AT Anghel, DJ Wales, SJ Jenkins, DA King - The Journal of Chemical Physics (
2007)
126, 044710
(DOI:
10.1063/1.2429068)
Hydrogen bonds at metal surfaces: Universal scaling and quantification of substrate effects
G Jones, SJ Jenkins, DA King - Surface Science (
2006)
600, L224
(DOI:
10.1016/j.susc.2006.05.053)
Ridge-bridge adsorption of molecular oxygen on Pt{110}(1 × 2) from first principles
MA Petersen, SJ Jenkins, DA King - J Phys Chem B (
2006)
110, 11962
(DOI:
10.1021/jp057447k)
The local adsorption geometry and electronic structure of alanine on Cu{110}
G Jones, LB Jones, F Thibault-Starzyk, EA Seddon, R Raval, SJ Jenkins, G Held - Surface Science (
2006)
600, 1924
(DOI:
10.1016/j.susc.2006.02.033)
Dissociative adsorption and adsorbate-induced reconstruction on Fe{211}
SJ Jenkins - Surface Science (
2006)
600, 1431
(DOI:
10.1016/j.susc.2005.12.064)
Comment on: New electron states that float on semiconductor and metal surfaces [Surf. Sci. 585 (2005) L177]
SJ Jenkins - Surface Science (
2006)
600, 1415
(DOI:
10.1016/j.susc.2005.11.039)
Funding
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