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1. 1 Crystallographic Concepts GLY 4200
Fall, 2011
2. 2 Atomic Arrangement Minerals must have a highly ordered atomic arrangement
The crystal structure of quartz is an example Images: http://www.infotech.ns.utexas.edu/crystal/quartz.htmImages: http://www.infotech.ns.utexas.edu/crystal/quartz.htm
3. 3 Quartz Crystals The external appearance of the crystal may reflect its internal symmetry Photos: http://www.msm.cam.ac.uk/doitpoms/tlplib/atomic-scale-structure/single1.phpPhotos: http://www.msm.cam.ac.uk/doitpoms/tlplib/atomic-scale-structure/single1.php
4. 4 Quartz Blob Or the external appearance may show little or nothing of the internal structure
5. 5 Building Blocks A cube may be used to build a number of forms Images: http://www.gly.uga.edu/schroeder/geol3010/externalforms1.gif and http://www.gly.uga.edu/schroeder/geol3010/externalforms2.gifImages: http://www.gly.uga.edu/schroeder/geol3010/externalforms1.gif and http://www.gly.uga.edu/schroeder/geol3010/externalforms2.gif
6. 6 Fluorite Fluorite may appear as octahedron (upper photo)
Fluorite may appear as a cube (lower photo), in this case modified by dodecahedral crystal faces
Photos: http://www.gc.maricopa.edu/earthsci/imagearchive/fluorite.htmPhotos: http://www.gc.maricopa.edu/earthsci/imagearchive/fluorite.htm
7. 7 Crystal Growth Ways in which a crystal can grow:
Dehydration of a solution
Growth from the molten state (magma or lava)
Direct growth from the vapor state
8. 8 Unit Cell Simplest (smallest) parallel piped outlined by a lattice
Lattice: a two or three (space lattice) dimensional array of points
9. 9 Lattice Requirements Environment about all lattice points must be identical
Unit cell must fill all space, with no holes
10. 10 Auguste Bravais Found fourteen unique lattices which satisfy the requirements
Published tudes Crystallographiques in 1849 Photo: http://euromin.w3sites.net//textesensmp/Repere/pic_hist/bravais0.jpgPhoto: http://euromin.w3sites.net//textesensmp/Repere/pic_hist/bravais0.jpg
11. 11 Isometric Lattices P = primitive
I = body-centered (I for German innenzentriate)
F = face centered
a = b = c, a = = ? = 90
12. 12 Tetragonal Lattices a = b ?c
a = = ? = 90
13. 13 Tetragonal Axes The tetragonal unit cell vectors differ from the isometric by either stretching the vertical axis, so that c > a (upper image) or compressing the vertical axis, so that c < a (lower image)
14. 14 Orthorhombic Lattice a ? b ?c
a = = ? = 90
C - Centered: additional point in the center of each end of two parallel faces
15. 15 Orthorhombic Axes The axes system is orthogonal
Common practice is to assign the axes so the the magnitude of the vectors is c > a > b
16. 16 Monoclinic Lattice a ? b ?c
a = ? = 90 ( ? 90 )
17. 17 Monoclinic Axes The monoclinic axes system is not orthogonal
18. 18 Triclinic Lattice a ? b ?c
a ? ? ? ? 90
19. 19 Triclinic Axes None of the axes are at right angles to the others
Relationship of angles and axes is as shown
20. 20 Hexagonal Some crystallographers call the hexagonal group a single crystal system, with two divisions
Rhombohedral division
Hexagonal division
Others divide it into two systems, but this practice is discouraged
21. 21 Hexagonal Lattice a = b ? c
a = ? = 90
= 120
22. 22 Rhombohedral Lattice a = b = c
a = = ? ? 90
23. 23 Hexagonal Axes The hexagonal system uses an ordered quadruplicate of numbers to designate the axes
a1, a2, a3, c
24. 24 Arrangement of Ions Ions can be arranged around the lattice point only in certain ways
These are known as point groups
25. 25 Crystal Systems The six different groups of Bravais lattices are used to define the Crystal Systems
The thirty-two possible point groups define the crystal classes
26. 26 Point Group Point indicates that, at a minimum, one particular point in a pattern remains unmoved
Group refers to a collection of mathematical operations which, taken together, define all possible, nonidentical, symmetry combinations
