PHYS 430/603 material Laszlo Takacs UMBC Department of Physics Lecture 3: More on Structures, Miller Indeces, Stereographic Projection PHYS 430/603 material Laszlo Takacs UMBC Department of Physics
Crystal structure data from http://cst-www.nrl.navy.mil/lattice/ The three most essential crystal structures FCC, Cu , A1, cF4 HCP, Mg, A3, hP2 BCC, W, A2, cI2 What other information is there? Space group/ set of symmetries Number of space group (arbitrary) Other substances with the same structure Primitive translational vector of the lattice (of mathematical points) Basis vectors describing the position of atoms in the basis Different ways to view the structure
Some compound structures that derive from fcc with insterstitial sites filled: TiN (NaCl structure) N at octahedral sites, as many as atoms TiH2 (CaF2 structure) H at tetrahedral sites, twice as many as atoms TiH (ZnS, zinc blende) H only in every other tetrahedral site; related to diamond Ti alone is hcp.
The size of atoms varies amazingly little, given the large increase in the number of electrons. Especially true for the meals used in typical alloys. Notice the small sizes of H, B, C, N. Defining the size of atoms is not trivial, they are not rigid balls. The atom-atom distance depends on the character of the bond. Ionic radii are much different, small for positive, Large for negative.
The metal lattice is rearranged to create a larger interstitial site The metal lattice is rearranged to create a larger interstitial site. The Al2Cu (C16) structure of Fe2B
The NRL site on Al2Cu Al2Cu prototype. tI12: Body centered tetragonal with 12 atoms in the unit cell. C16: The 16th A2B structure. I4/mcm: Space group symbol. 140: Arbitrary number assigned to the space group. X, Y, Z: Unit vectors in the directions of the unit cell axes; a, c lattice parameters. Atom positions within the unit cell are given for only one of the equivalents. Notice that x has to be determined from measurement.
The elementary vectors of translation, i. e The elementary vectors of translation, i.e. the edges of the elementary cell, define the unit vectors of our coordinate system. Directions and planes are defined in this coordinate system. It is identical to the ordinary rectangular coordinate system with identical scales only for cubic structures. c b a
Defining directions and planes Directions defined by a vector: r = ua + vb + wc Usually we are interested in directions where u, v, w are small integers. Standard notation for a direction: [u v w] Notation for all equivalent directions: < u v w > There is no comma between numbers, “-” sign put over the numbers. Set of parallel planes described by Miller indeces Note the intersections with the axes in units of a, b, c; typically small integers. Put down infinity, if the plane is parallel to the axis. Take the reciprocal of the three numbers, 0 for infinity. Multiply with the smallest number that gives a set of integers. Notation for a single plane: (m n q) Notation for a set of equivalent planes: {m n q} In the cubic system (and only there) [m n q] is the normal of (m n q).
Some planes of the [0 0 1] zone (A zone is the set of all planes that are parallel to the given direction. Weiss zone law: hu + kv + lw =0)