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CENG 511 Lecture 3. Surface Structure of Catalysts Dr. King Lun Yeung Department of Chemical Engineering Hong Kong University of Science and Technology. Langmuir-Hinshelwood reaction. Heterogeneous Catalysis. Eley-Rideal reaction.
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CENG 511 Lecture 3 Surface Structure of Catalysts Dr. King Lun Yeung Department of Chemical Engineering Hong Kong University of Science and Technology
Langmuir-Hinshelwood reaction Heterogeneous Catalysis Eley-Rideal reaction adsorption, surface diffusion, surface reaction, desorption
FCC HCP Crystals and Crystal Structures Metal Semiconductor Insulator
Face Centered Cubic (FCC) Crystal Coordination Number Number of Atoms per Unit Cell
Hexagonal Close Packed (HCP) Crystal Number of Atoms per Unit Cell Atomic Packing Factor Coordination Number
Bulk Structure (Crystalline Solid) Cubic Simple bcc fcc Diamond Crystal Structure http://ece-www.colorado.edu/~bart/book/bravais.htm
Surface Structure Surface Bulk Metal Cleave
Miller Indices <001> (100) <010> <100> (110) (111) http://www.chem.qmw.ac.uk/surfaces/scc/scat1_1b.htm
(110) (100) (111) Surface Structure of Platinum (Ideal) http://www.chem.qmw.ac.uk/surfaces/scc/scat1_2.htm
Surface Structure Surfaces are usually rough consisting of high miller index planes
Surface Structure Surface Sites Planar atoms Edge atoms Corner atoms Adatoms Kinks Defect terrace step
Surface Cleave Bulk Metal Surface Energetics Energy is needed to create surface DG > 0 In order to minimize DG (1) smaller surface area (2) expose surface with low DG (3) change atomic geometry (relaxation and reconstruction)
Surface Relaxation and Reconstruction Surface Relaxation spontaneous adsorbent driven http://www.chem.qmw.ac.uk/surfaces/scc/scat1_6.htm
Surface Relaxation and Reconstruction Surface Reconstruction spontaneous adsorbent driven Normal (100) Surface Reconstructed Surface http://www.chem.qmw.ac.uk/surfaces/scc/scat1_6.htm
Surface Structure is Dynamic UHV W(001) c(2x2) H2 chemisorption W(001) c(2x2)
Surface Structure is Dynamic Effect of Oxygen Adsorbent W(110)
Surface Structure Determination Low Energy Electron Diffraction (LEED) Analyzes surface crystallographic structure by bombarding the surface with low energy electrons (10-200 eV) and the diffracted electrons creates patterns on phosphorescent screen. The pattern of spots contains information of surface structure and the spot intensity indicates reconstruction http://electron.lbl.gov/leed/leedtheory.html http://dol1.eng.sunysb.edu/expcht1.html
grid screen electron gun LEED Device L = d sinq http://www.chem.qmw.ac.uk/surfaces/scc/scat6_2.htm
LEED Theory http://www.chem.qmw.ac.uk/surfaces/scc/scat6_2.htm
LEED Theory LEED patterns are reciprocal net of surface structure a1* a2a2* a1 a1* a1 a2* a2 a1* =1/ a1 a2* =1/ a2
FCC LEED Patterns BCC LEED Patterns Low Energy Electron Diffraction
Surface Structure Determination Low Energy Electron Microscopy (LEEM) Objective lense http://www.research.ibm.com/journal/rd/444/tromp.html
Surface Structure (LEEM) LEED Pattern Si (001) LEEM
Photoelectron emission microscopy (PEEM) Phase Contrast (terraces and steps) UV-excitation, work function contrast Higher vertical resolution, lateral resolution ~ 5 nm Other LEEM imaging
Reflection High Energy Electron Diffraction (RHEED) Advantages better sample geometry atom-by-atom growth Disadvantages sampling of two alignment needed
Surface Structure (Field electron and Field ion microscopy) FEM FIM Tip Nickel Surface structure http://www.nrim.go.jp:8080/ open/usr/hono/apfim/tutorial.html Work function
Real Catalyst Surface Catalyst has been annealed in hydrogen at 873 K for 60 h http://ihome.ust.hk/~ke_lsy/yeung/
Highly dispersed metal on metal oxide Nickel clusters SiO2 Supported Catalyst highest lowest 55 atom cluster surface energy minimization http://brian.ch.cam.ac.uk/~jon/PhD2/node19.html
Supported Molybdenum Sulfide Formation of stable raft or island structure with geometrical shape
Supported Catalyst Influence of support substrate Unrolling carpet Defect diffusion Surface wetting and spreading mechanism
Real Catalyst Surface Catalyst wets support Catalysts are usually small particles or cluster that can exhibit several crystallographic planes of different surface atomic structures Catalyst does not wet support
Metal-Support Interaction Experimental evidence of encapsulation Model SIMS SIMS
e- Metal-Support Interaction Electronic effects of SMSI Metal-metal oxide junction Metal catalyst This can change the electronic properties of the metal catalyst by either pulling away or adding electrons from metal to oxide support Metal oxide partially reduced metal oxide
Supported Metal Oxide Catalyst MoO2 catalyst SiO2 Support
[010] ( Straight channel) [001] Viewed along [010] [100] ( Sinusoidal channel) Viewed along [100] Surface Structure Surface usually refers to the to 2-8 monolayer of atoms at the interface of a solid Nanoporous materials Molecular sized pores
Zeolite Catalysts p-xylene m-xylene Pore size = 5.5 Å External surface area = 50 m2/g Total surface area = 400 m2/g
Y-zeolite Molecules in Zeolite Cages and Frameworks + p-xylene ZSM-5 Paraffins
Pt cluster (< 50 nm) High temperature annealing in hydrogen High temperature annealing in nitrogen Genesis of Catalyst Crystallites http://www.lassp.cornell.edu/sethna/CrystalShapes
Rough surface Genesis of Catalyst Crystallites Pt cluster (< 50 nm) Surface structural sites well-defined structure, low miller index planes, high-coordinated surface atoms facets rough surface, high miller index planes, low-coordinated surface atoms
CH3 CH = CH CH3 CH3 H3C H3C CH = CH CH - CH Pt C H3C Pt Pt 2-butene molecule adsorption on Platinum Pt CH - CH CH3 Pt Pt Pt Pt Molecules on Surface Ordered Adsorbate layer cinchonidine on Platinum
Surface Structure = Adsorption/Catalytic Sites Surface structural sites serves as adsorption and catalytic sites for molecules
Calculated crystal shape based on thermodynamics calculation Equilibrium-shaped Au Crystallite Crystal Morphology
Possible Crystallite Morphologies ARCHIMEDEAN SOLIDS Crystal facets will correspond to (111), (100) and (110) planes of a cubic crystal
NS/NT dc (Å) Dispersed Catalysts Truncated Octahedron Crystal size then NS/NT
Increasing stability Icosahedron Random Cubo-octahedron Crystallite Single Facet (111) Amorphous No Facets Crystallite Two Facets (111) and (100) Shape Transformation
Supported Catalysts Metal supported on metal oxide Coarsening