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Quasicrystals. AlCuLi QC Rhombic triacontrahedral grain. Typical decagonal QC diffraction pattern (TEM). Quasicrystals. Diffraction pattern for 8-fold QC. Diffraction pattern for 12-fold QC. Quasicrystals. Principal types of QCs: icosahedral decagonal. Quasicrystals.
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Quasicrystals AlCuLi QC Rhombic triacontrahedral grain Typical decagonal QC diffraction pattern (TEM)
Quasicrystals Diffraction pattern for 8-fold QC Diffraction pattern for 12-fold QC
Quasicrystals Principal types of QCs: icosahedral decagonal
Quasicrystals Principal types of QCs: icosahedral decagonal metastable (rapid solidifcation) stable (conventional solidification)
Quasicrystals Principal types of QCs: icosahedral decagonal metastable (rapid solidifcation) stable (conventional solidification) QCs usually have compositions close to crystalline phases - the "crystalline approximants"
Quasicrystals While pentagons (108° angles) cannot tile to fill 2=D space, two rhombs w/ 72° & 36° angles can - if matching rules are followed N.B. - see definitive & comprehensive book on tiling by Grünbaum and Shepherd
Quasicrystals While pentagons (108° angles) cannot tile to fill 2=D space, two rhombs w/ 72° & 36° angles can - if matching rules are followed
Quasicrystals Fourier transform of this Penrose tiling gives a pattern which exhibits 5 (10) - fold symmetry – very similar to diffraction patterns for icosahedral QCs
Quasicrystals t 1 Diffraction pattern (in reciprocal space) of icosahedral QC can be indexed w/ 6 six integers - axes along 6 icosahedron directions qi (referred to Cartesian qx, qy, qz)
Quasicrystals t 1 Diffraction pattern (in reciprocal space) of icosahedral QC can be indexed w/ 6 six integers - axes along 6 icosahedron directions qi (referred to Cartesian qx, qy, qz) q1= (1 t 0) q2= (t 0 1) q3= (t 0 1) q4= (0 1 t) q5= (1 t 0) q6= (0 t 1)
Quasicrystals t 1 t =(1 + 5)2 = 1.618… Diffraction pattern (in reciprocal space) of icosahedral QC can be indexed w/ 6 six integers - axes along 6 icosahedron directions qi (referred to Cartesian qx, qy, qz) q1= (1 t 0) q2= (t 0 1) q3= (t 0 1) q4= (0 1 t) q5= (1 t 0) q6= (0 t 1)
Quasicrystals Diffraction pattern (in reciprocal space) of icosahedral QC can be indexed w/ 6 six integers - axes along 6 icosahedron directions qi (referred to Cartesian qx, qy, qz) q1= (1 t 0) q2= (t 0 1) q3= (t 0 1) q4= (0 1 t) q5= (1 t 0) q6= (0 t 1) Thus, icosahedral QC is periodic in 6D
Quasicrystals Also consider: to periodically tile in 2-D – need three translation vectors if 5-fold, reasonable cell is pentagon – need additional dimension to fill space (tile) – more translation vectors
Quasicrystals Diffraction pattern (in reciprocal space) of icosahedral QC can be indexed w/ 6 six integers - axes along 6 icosahedron directions qi (referred to Cartesian qx, qy, qz) q1= (1 t 0) q2= (t 0 1) q3= (0 1 t) q4= (1 t 0) q5= (t 0 1) q6= (0 1 t) Thus, icosahedral QC is periodic in 6D But not in 3D To understand this, consider periodic 2D crystal:
Quasicrystals To understand this, consider periodic 2D crystal: The 2D crystal is not in our observable world - what IS seen is the cut along E But cut along E may or may not pass through lattice nodes Cut shown has slope 1/ t - does not pass through lattice nodes except origin
Quasicrystals To understand this, consider periodic 2D crystal: But can observe both real structure and diffraction pattern for this 1D quasiperiodic crystal Must be some kind of structure in the extended space (the 2nd dimension) - shown here as lines through the 2D lattice nodes
Quasicrystals To understand this, consider periodic 2D crystal: Must be some kind of structure in the extended space (the 2nd dimension) - shown here as lines through the 2D lattice nodes Some of the lines intersect "the real world" cut E, thereby allowing observation of the real quasiperiodic structure
Quasicrystals To understand this, consider periodic 2D crystal: Note short & long segments in real real world cut - form "Fibonacci sequence": s l sl lsl sllsl lslsllsl sllsllslsllsl …….. if s = 1, l = t
Quasicrystals To understand this, consider periodic 2D crystal: Think of 2 spaces - "parallel" (real) & "perp" (extended)
Quasicrystals Consider incommensurate crystals: Need additional dimension to completely describe structure
Quasicrystals Consider incommensurate crystals: Similar to quasiperiodic case
Quasicrystals There are 16 space groups for the 6-D point group 532 w/ P, I, F 6-d cubic lattices The 6-D structure & the parallel & perpendicular subspaces are all invariant under the operations of 532
Quasicrystals There are 16 space groups for the 6-D point group 532 w/ P, I, F 6-d cubic lattices The 6-D structure & the parallel & perpendicular subspaces are all invariant under the operations of 532 To visualize 6-D structure, must make 2-D cuts which necessarily must show both parallel & perp spaces
Quasicrystals There are 16 space groups for the 6-D point group 532 w/ P, I, F 6-d cubic lattices The 6-D structure & the parallel & perpendicular subspaces are all invariant under the operations of 532 To visualize 6-D structure, must make 2-D cuts which necessarily must show both parallel & perp spaces This cut has 2-folds along parallel & perp directions
Quasicrystals More on indexing – Note strangeness of axial directions – 63.43° from q1
Quasicrystals More on indexing – Use Cartesian system – basis vectors down 3 2-folds Then indices are: (h+h't, k+k't, l+l't) Usually given as: (h/h' k/k' l/l') Ex: (210010) ––> (2/2 0/2 0/0) (111111) ––> (0/2 2/2 0/0)
