1. MRSEC Teacher Institute�15 March 2005
Introduction to
Crystal Structures
Janet Rankin
Division of Engineering
2. Objectives By the end of this session, participants will:
have considered how the arrangement of atoms in crystals influences material properties
be able to recognize a few simple crystal structures
have learned how to designate the positions of atoms within a crystal structure,
be acquainted with the rules for specifying direction within a crystal structure
have considered ways in which the introduction of crystal structures into K-12 curricula can help students learn a variety of mathematical and scientific concepts
3. How are atoms arranged in solids?? 3 phases or states of matter
Solid
Liquid
Gas
The solid state
Atoms in solids may be randomly positioned (as in a liquid) – Amorphous Solids (e.g. glasses) or
Arranged in an orderly, repeating pattern within the material – Crystalline Solids
4. �How do we describe the arrangement of atoms in crystals?
Specify a LATTICE
Specify the POSITIONS of atoms in the lattice
5. �What’s a Lattice?
There are 14 (only) Bravais Lattices
there are only 14 unique ways to fill space with a periodic arrangement of points. A lattice is like scaffolding
Once you specify the lattice, you can then “decorate” your lattice with a collection of atoms. Each lattice point must be decorated with the same collection of atoms.
6. “Constructing” a Crystal Once you specify the lattice, you can then “hang” a collection of atoms off of each position in the lattice
Important: every lattice point (point on the scaffold) must have the exact same enviroment. i.e. the structure must possess translational symmetry from point to point.
Look at 2-D examples: Escher prints
7. 2-D “Crystals” M.C. Escher:
http://home.comcast.net/~eschermc/
Sea horses
Bugs
Moths
Fish
Flying Fish
Birds
Menagerie
Butterflies
8. Metallic Crystals
9. Metallic Crystal Structures The atoms in most simple metals are arranged in one of the configurations below
Simple Cubic (sc) - Po
Body-Centered Cubic (bcc) – Ba, Cs, Cr
Face-Centered Cubic (fcc) – Cu, Ag,
Hexagonal Close-Packed (hcp) – Zn, Co
Nearest-neighbors atoms “touch” in all of these cases.
10. Characteristics of Selected Elements at 20C
11. Specifying Directions in a �(cubic) Crystal Choose a right-handed coordinate system
Pick an origin for your set of axes
the x-axis is the vector (100)
the y-axis is the vector (010)
the z-axis is the vector (001)
Any direction in the crystal can be defined using the basis above.
12. Materials Science Links Crystal Structures
Naval Research Labs – “interactive” crystal structure
http://cst-www.nrl.navy.mil/lattice/
University of Arizona – Geology Department
http://www.geo.arizona.edu/AMS/amcsd.php
More Crystal Structures
http://www.chem.ox.ac.uk/icl/heyes/structure_of_solids/Strucsol.html
Stereo Pairs
http://www.chem.lsu.edu/htdocs/people/sfwatkins/ch4570/lattices/lattice.html
MERLOT
http://wb.chem.lsu.edu/htdocs/people/sfwatkins/MERLOT/flattice/00lattice.html
13. Construction of a Crystal Model Supplies needed:
Styrofoam, clay, or candy spheres (atoms)
Wood or plastic connectors, e.g. dowels or toothpicks, coffee stirrers, spaghetti (bonds).
Choose fcc, or bcc structure.
14. Construction of a Crystal Model Things to consider:
Which atoms are touching in your structure?
What is the Coordination Number (CN) in your crystal? (How many nearest neighbors does each atom have?)
Can you identify a line (direction) in which the atoms touch?
Can you relate the size of the atom to the size of the unit cell? (i.e. write an expression for a = f(r))
15. Crystals as Building Blocks
16. Polycrystalline Materials
17. Single v. Polycrystals
18. Break-Out Session:�How might you use this in your classroom? suggestions for student activities:
Model construction and analysis
Identify coordinates (positions) of atoms in various structures
I.D directions
Geometry exercises (distances in unit cells)
I.D. symmetry operators (translation, rotation, mirror)
Notes from discussions
19. Materials Science Links General Links
Materials Research Society
(http://www.mrs.org/microworld)
University of Arizona’s science e-zine (see the “gallery” on the left side-bar)
http://researchmag.asu.edu/materials_4.html
University of Connecticut - simulations of a variety of phenomena in materials science (p.c. - only)
http://ims.uconn.edu/centers/simul/movie
CS 92 - Educational Software Seminar
http://www.cs.brown.edu/courses/cs092/2001/splash/
(see Spring 2001 projects for “Splash” [p.c.- only, < XP])
20.
Contact Information
Janet_Rankin@brown.edu
863-9192
21. SIMPLE CUBIC STRUCTURE (SC)
22. Hexagonal Close-Packed Structure (hcp)
23. Body-Centered Cubic (BCC)
24. Face-Centered Cubic (FCC)
25. Hexagonal Close-Packed
26. Specifying Directions in Crystals
27. Notes from Discussion In order to use these concepts effectively in K-12 classes, more background knowledge would be necessary (i.e. teachers would have to do more research into crystalline structures).
Felt that this could be used as a “real life” application of Pythagorean Theorem
Could be used in chemistry classes: e.g. make NaCl, ZnI2, crystals and then consider various aspects of crystallography, compare, contrast, etc.
Different models for solid, liquid and gaseous states
Could be used to present vectors in algebra II classes.
