Bulk Structures of Crystals

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Bulk Structures of Crystals 7 crystal systems can be further subdivided into 32 crystal classes... see Simon Garrett, "Introduction to Surface Analysis CEM924": http://www.cem.msu.edu/~cem924sg/lecturenotes.html

Bulk Structures of Crystals 2 lattice features of ideal crystals: "asymmetric unit": elementary building blocks of a crystal, the "basis" (atoms, molecules, proteins, colloids...) "space lattice": 3D infinite array of points (locations of asymmetric unit assemblies), surrounded in an identical way by neighbors "crystal structure": blue print of the exact positions of asymmetric units in the space lattice (location, orientation) "unit cell": fundamental unit (arrangement of one ore more asymmetric units) from which the entire crystal can be generated by translational symmetry operations (like the bricks in a regular wall)

2D lattices: Bulk Structures of Crystals 3 14 Bravais lattices: C 1 C 2 C 3 C 4 (unit cells) C 5 C 6 C 7 dense packing only possible with C n : n = 1,2,3,4,6

Important Basic Crystal Structures The three most common basic crystal structures are fcc, hcp, and bcc. first layer: hexagonally close packed fcc: face centred cubic, coordination number CN = 12 = second layer: sits in hollow sites occupied volume = 74% hcp: hexagonal close packed, CN = 12 bcc: body centred cubic, CN = 8 third layer: two possible locations hcp..abab.. "on top" fcc..abca.. "on hole" occupied volume = 74% occupied volume = 68% see Roger Nix, "An Introduction to Surface Chemistry": http://www.chem.qmw.ac.uk/surfaces/scc/

Crystal Planes Miller Indices The planes of ideal crystals (a cut through the lattice) are closely related to ideal crystal surfaces. To specifiy a particular plane most commonly Miller indices are used. 1) 2) 3) note: hexagonal and trigonal lattices use 4 Miller indices by convention (redundant)! 1 / (1,, ) = (1 0 0) Procedure: 1) Identify intercepts of plane on the x, y, and z axes. 1 x a, x b, x c (example: cubic lattice a=b=c, = = =90 ) 2) Specify intercepts in fractional coordinates of unit cell parameters a, b, c. (1 x a) / a, ( x b) / b, ( x c) / c 1,, 3) Take reciprocal of fractional intercepts, clear fractions. 1 / (1,, ) = (1 0 0) bar for negative values h k l for cubic lattice: (100), (010), (001) are identical R = (120)

Simple 2D Lattices translation vectors, unit cell vectors: a, b example: Au (100) surface conventional bulk unit cell primitive surface unit cell primitive cell obeys translation symmetry see also "Wallpaper Groups: lattices": http://aleph0.clarku.edu/~djoyce/wallpaper/lattices.html

low index surfaces: fcc (100) Ideal Crystal Surfaces bcc high index surfaces: (755) (100) (111) Pt(755) or Pt S [7(111)x(100)] (110) stepped surface (100) step 1 atom high (111) terrace 7 atoms wide (111) (10 8 7) (310) (111) compound surface: NaCl(100) Pt(10 8 7) or Pt S [7(111)x(310)] (steps with kinks)

Real Crystal Surfaces Reconstruction and Superlattices Relaxation: Reconstruction: Superlattices: non relaxed distance change < 10% Substantial rearrangement unit surface cell different from the bulk projected substrate relaxed driving force: unbalanced forces compared to bulk satisfying dangling bond Si(100) (2x1) bulk atom Si(111) (7x7) surface atom ( 2x 2),R45

Surface Defects and Structures monoatomic step terrace adatom (mobile) step adatom step vacancy (mobile) kink surface defects are important for crystal growth: traps for newly adsorbed atoms / molecules restructuring of surfaces happens at defects first kink, step, and terrace atoms have large equilibrium concentrations on real surfaces (hard to get perfect surface...) isolated adatoms and vacancies are important for atomistic transport (restructuring), but equilibrium concentration is low (< 1% of monolayer even at T melt )

Persistent Defects: Dislocations "dislocations": stacking faults that disrupt regularity of crystal kinetically: adsorbing species does not have enough time to find thermodynamic equilibrium (correct position) composition: adsorbing impurity atom disrupts packing point defect, missing atom, impurity: screw dislocation: propagates through crystal step dislocation, line defect: dislocations contribute to mechanical properties (ductility, brittleness) and influence crystallization speed (trapping sites)

Other Defect Structures mosaic: composition of "real" (imperfect) crystal of many small "ideal" (perfect) crystallites (diameter about 10 7 m) with slight misalignment of crystal axes (like rectangular bricks in an irregular wall) domain borders relate to step dislocations Frenkel Schottky defect: in ionic crystals, explains high electric conductivity in such materials Frenkel: dislocation of a single ion + + + + + to an interlattice site + + + + + + + Schottky: dislocation of single ion to crystal surface or stacking defect color center: alkali halogenide crystals > excess of metal atoms with free electrons located in the lattice > optical absorption (specific for lattice, not for metal type: K or Na)

Surface Sites and Adsorbate Surface Structures Adsorption Sites: bridge four fold hollow Adsorbate Surface Structures: three fold hollow on top fcc (100) c(2x2) or fcc(100) ( 2x 2)R45 short bridge four fold hollow on top bridge fcc (100) p(2x2) or fcc(100) (2x2) 2 fold hollow fcc(111) ( 3x 3)R30 long bridge hcp hollow (ABA...) fcc hollow (ABC...) fcc (100) (2x1)

Wood s Notation and Matrix Notation Description of the ordered adlayer (adsorbed atoms and molecules) in terms of the relationship to the underlying ideal crystal plane. examples: fcc(100) alternatively: for p( 2x 2)R45

bulk surface Electronic and Vibronic Features of Surfaces potential energy atom spring model atom molecule 1D solid 1D solid with surface vibronic band structure electronic band structure probability density phonon wave vector: k vib = 2 vib with vib : phonon wave length, a : lattice constant electron wave vector: k = 2 with : electron wave length, a : lattice constant E pot : potential energy, E vib : vibonic energy, E el : electronic energy, E ss : energy of the surface state

Electronic and Vibronic Features of Surfaces 2 STM image of Fe atoms on Cu(111): electronic surface states (particel in a box) SPR (surface plasmon resonance) setup: optical coupling in electronic surface states (fluorescence) SAW (surface acoustic wave) sensor: horizontally propagating acoustic surface waves