Unit 1: Crystallography Practicals
Table of Contents
Introduction to Practical Crystallography
This practical unit focuses on understanding the external 3D geometry of crystals. The core concept is that a crystal's internal atomic arrangement is expressed externally through its faces and symmetry. Your goal is to be able to identify the symmetry elements in a crystal model and represent its 3D form in 2D using stereographic projection. This practical is based on the theory from GEL-DSC-102.
Study of Crystal Symmetry Elements
Symmetry elements are imaginary geometric operations that describe the regularity of a crystal's form. In the lab, you will use wooden or plastic crystal models to find these elements.
The Three Main Symmetry Elements
- Axis of Symmetry (Rotation Axis):
- What it is: An imaginary line through the crystal's center. When the crystal is rotated around this axis, it appears identical more than once in a 360° turn.
- Types:
- 2-fold (Diad): Looks the same every 180° (2 times).
- 3-fold (Triad): Looks the same every 120° (3 times).
- 4-fold (Tetrad): Looks the same every 90° (4 times).
- 6-fold (Hexad): Looks the same every 60° (6 times).
- How to find it: Hold the model between your fingers (at opposite faces, edges, or corners) and rotate it to see how many times it repeats.
- Plane of Symmetry (Mirror Plane):
- What it is: An imaginary flat plane that divides the crystal into two identical halves, where one half is the mirror image of the other.
- How to find it: Imagine slicing the crystal with a "mirror." If the half on one side reflects perfectly onto the half on the other, you've found a plane.
- Center of Symmetry (Inversion Center):
- What it is: An imaginary point in the center of the crystal. Any line drawn from a face or corner through the center will emerge at an identical point on the opposite side.
- How to find it: Check if every face has an identical, inverted, parallel face on the opposite side of the crystal. A cube has a center; a tetrahedron does not.
Crystal Systems, Normal Classes, and Forms
A Form is a set of identical crystal faces that are related by symmetry (e.g., the 6 identical faces of a cube). The Normal Class (or Holohedral Class) of each system is the class with the highest possible symmetry.
- Axes: 3 axes of 4-fold, 4 axes of 3-fold, 6 axes of 2-fold.
- Planes: 9 planes (3 parallel to faces, 6 diagonal).
- Center: 1 center of symmetry.
Summary of Normal Classes and Common Forms
| Crystal System | Normal Class Symmetry (H-M Symbol) | Key Symmetry Elements | Common Forms |
|---|---|---|---|
| Cubic | 4/m 3 2/m | Multiple 4-fold and 3-fold axes. | Cube, Octahedron, Dodecahedron. |
| Tetragonal | 4/m 2/m 2/m | One 4-fold axis. | Prism, Dipyramid (both tetragonal). |
| Hexagonal | 6/m 2/m 2/m | One 6-fold axis. | Prism, Dipyramid (both hexagonal). |
| Trigonal | 3 2/m | One 3-fold axis. | Rhombohedron, Scalenohedron. |
| Orthorhombic | 2/m 2/m 2/m | Three 2-fold axes at 90°. | Rhombic Prism, Dipyramid, Pinacoids. |
| Monoclinic | 2/m | One 2-fold axis. | Prisms, Pinacoids. |
| Triclinic | 1 | Only a center (or none). Lowest symmetry. | Pinacoids. |
Stereographic Projection
This is the main practical exercise. A stereographic projection is a 2D map that accurately represents the 3D angular relationships of crystal faces and symmetry elements.
Practical Objective
To plot the poles (imaginary lines perpendicular to each crystal face) onto a 2D circle (the stereogram). This allows you to visualize all crystal faces and their symmetry on a single diagram.
Tools Needed
- A Wulff Net: A circular grid of latitude and longitude lines.
- Tracing paper and a thumb tack.
- A protractor and ruler.
Step-by-Step Guide (General)
- Setup: Place the tracing paper over the Wulff Net, secured at the center with the tack. Draw the basic circle (called the primitive circle).
- Orient the Crystal: Imagine the crystal at the center of a sphere. The vertical c-axis exits at the top (North Pole) and the a/b axes are on the horizontal (Equator) plane.
- Plotting Faces (Poles):
- A face on the top of the crystal (e.g., (001)) plots as a dot (•) at the center.
- A face on the bottom (e.g., (00-1)) plots as a small circle (○) at the center.
- Faces on the horizontal/vertical sides (e.g., (100), (010)) plot on the outer primitive circle.
- Inclined faces plot inside the circle. You'll measure their angles (rho, phi) and use the Wulff net to find their precise location.
- Plotting Symmetry:
- Symmetry axes are marked at their exit points with symbols (■ for 4-fold, ▲ for 3-fold, etc.).
- Symmetry planes are drawn as bold lines (either straight diameters or curved great circles).
- Plot the faces and symmetry elements for a simple crystal (like a cube or a tetragonal prism).
- Be given a finished stereogram and be asked to identify the crystal system and symmetry elements from it.