| Line 53: | Line 53: | ||
body-centered cubic structure is similar to the simple cubic structure but with an added <br> | body-centered cubic structure is similar to the simple cubic structure but with an added <br> | ||
atom in the center of the unit cell. The face-centered cubic structure is also similar <br> | atom in the center of the unit cell. The face-centered cubic structure is also similar <br> | ||
| − | to the simple cubic structure but with added atoms in the center of all 6 cube faces. | + | to the simple cubic structure but with added atoms in the center of all 6 cube faces. <br> |
| + | These structures can also be defined by their coordination numbers, or the number of <br> | ||
| + | nearest neighboring atoms. For the simple cubic structure, there are 6 nearest neighbors, <br> | ||
| + | corresponding to a coordination number of 6. The face-centered cubic structure has a <br> | ||
| + | coordination number of 12 and the body-centered cubic structure has a coordination number <br> | ||
| + | of 8. | ||
'''Crystal Movement and Symmetry'''<br><hr><br> | '''Crystal Movement and Symmetry'''<br><hr><br> | ||
Revision as of 08:04, 17 November 2013
Crystals and Symmetry
NamesJason Krupp (krupp@purdue.edu)
Erik Plesha (eplesha@purdue.edu)
Andrew Wightman (awightma@purdue.edu)
Thilagan Sekaran(trajasek@purdue.edu)
A) Crystal Symmetries and Their Properties
--Miller Indices
--Slip Systems
--Group Properties
B) Crystal Movement and Symmetry
--Translational Movement
--Rotational Movement
--Mirror Movement
C)Combinations of Symmetry Operations
--32 Crystal Classes
D)Crystal Symmetry Groups
--Finite Symmetry Groups
--Non-Finite Symmetry Groups
Many important material properties depend on crystal structure. Some of these
include the following inexhaustive list: conductivity, magnetism, stiffness, and
strength.
Miller Indices represent an efficient way to label the orientation of the crystals.
For planes, the Miller Index value is the reciprocal of the value of the
intersection of the plane with a particular axis, converted to whole numbers and are
usually represented by round brackets (parenthesis). For directions in a crystal
lattice, the index is the axis coordinate of the end point of the vector, converted
to the nearest whole number and are usually represented by [square brackets].
For example, the figure above depicts 3 of the 6 cube faces and the corresponding
Miller Indices. The red plane is labeled as (100) because the plane is shifted 1
unit in the x-direction. The yellow plane is labeled (010) because it is shifted 1
unit in the y-direction. Finally, the green plane is labeled (001) because it is
shifted 1 unit in the z-direction. For more on Miller Indices, please visit the
link listed in the References Section.
Although Miller Indices does a great job of describing crystals, it doesn't complete
the job. Crystals can also be divided up according to their structure, the three most
common types being FCC (Face-Centered Cubic), BCC (Body-Centered Cubic), and SC
(Simple Cubic) structures.
As you can see, the above figure shows the three aforementioned crystal types. The
body-centered cubic structure is similar to the simple cubic structure but with an added
atom in the center of the unit cell. The face-centered cubic structure is also similar
to the simple cubic structure but with added atoms in the center of all 6 cube faces.
These structures can also be defined by their coordination numbers, or the number of
nearest neighboring atoms. For the simple cubic structure, there are 6 nearest neighbors,
corresponding to a coordination number of 6. The face-centered cubic structure has a
coordination number of 12 and the body-centered cubic structure has a coordination number
of 8.
Combinations of Symmetry Operations
Crystal Symmetry Groups
References and Links
Gallian, J. (2013). Contemporary abstract algebra. (8th ed.). Boston, MA: Brooks/Cole, Cengage Learning.
Miller Indices Link
Cubic Structures Link
