NANO106 is UCSD Department of NanoEngineering's core course on crystallography of materials taught by Prof Shyue Ping Ong. For more information, visit the course wiki at http://nano106.wikispaces.com.
2. Readings
¡Chapter 3 of Structure of Materials
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
3. What is a crystal?
¡A crystal is a time-invariant, 3D arrangement of
atoms or molecules on a lattice.
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
Perovskite SrTiO3
The “motif”
repeated on each point in the cubic
lattice below…
4. Nets and Lattices
¡A lattice (3D) or net (2D) is an abstract concept of
an infinite array of discrete points generated by a
set of translation operations.
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
The motif
Repeated
infinitely in all
directions
5. Concept of Symmetry
¡You have just encountered
your first symmetry concept
– translational symmetry.
¡A symmetry operation is a
permutation of atoms such
that the molecule or crystal
is indistinguishable before
and after the operation.
¡It also means that all lattice
points have exactly the
same “environment”.
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
6. Identify the nets in the following
patterns
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
7. Identify the nets in the following
patterns
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
8. Basis and translation vectors
¡ How are points in a lattice related to one another (e.g.
how do we get from point A to point B)?
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
A
B
b
a
Let us define basis vectors a and b.
All points in the lattice can therefore be
reached by integer linear combinations of the
basis vectors, i.e.,
By inspection, we can see that
If we choose A to be the arbitrary origin with
coordinates (0, 0), all other lattice points can
be represented as (u, v). For example,B = (2,
1). t is then known as the translation vector.
t
t = ua + vb, u,v ∈ Z
B- A = 2a + b
9. Basis and translation vectors
¡ For 3D lattices, there are three basis vectors instead of
two. Notationally,
¡ And each lattice point/node can be represented by
coordinates (u, v, w)
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
t = ua + vb+ wc, u,v,w ∈ Z
10. Net and Lattice parameters
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
a = Length of a
b = Length of b
c = Length of c
α = Angle between b and c
β = Angle between a and c
γ = Angle between a and b
a,b,c,α,β,γ{ }
a = Length of a
b = Length of b
γ = Angle between a and b
a,b,γ{ }
11. Lattice math example
¡A lattice is given by the following vectors in
Cartesian space:
¡ Calculate the lattice parameters a, b, c, α, β, γ.
¡ If a lattice node is given by coordinates (3, 2, 1) in
crystal coordinates, what are its coordinates in Cartesian
coordinates?
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
a =
1
0
0
!
"
#
#
#
$
%
&
&
&
, b=
−1/ 2
3 / 2
0
!
"
#
#
##
$
%
&
&
&&
, c =
0
0
3
!
"
#
#
#
$
%
&
&
&
Blackboard
12. Deriving the 2D Crystal Systems
¡ What values can take? Or phrased in another way,
what special values of would result in additional
symmetry?
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
a,b,γ{ }
a,b,γ{ }
Consider arbitrary
a,b,γ{ }
What are the symmetry
elements in this net?
The oblique net (and all 2D nets) has two-fold rotational symmetry.
13. Higher symmetry nets
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
a ≠ b,γ = 90°
a = b,γ = 90°
Rectangular net Square net
a = b,γ =120°
Hexagonal net
14. Adding new nodes
¡Can we get a new distinct net by adding more
lattice points to existing nets?
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
New centered rectangular
net, all nodes have the
same environment.
No new net!
If we reorient the lattice by 45
deg, we see that what we have
is simply a square net with
shorter vectors.
Not a net at all. All nodes
do not have the same
environment.
15. Rectangular
Five 2D nets
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
p: primitive
c: centered
(lower case for 2D)
International symbols for 2D nets
Oblique Square Hexagonal
Four 2D crystal systems
m: monoclinic
o: orthorhombic
t: tetragonal
h: hexagonal
16. Unit Cells
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
¡ A unit cell is simply a geometric unit that can be stacked
infinitely to reproduce the entire lattice.
¡ Primitive unit cells – only 1 lattice point in the cell
¡ Non-primitive cells – more than 1 lattice point in the cell
• Which of these cells are
primitive?
• How many lattice points
are there in each cell?
• Which cell(s) reflect the
full symmetry of the net?
17. The Wigner-Seitz Cell
¡ The Wigner-Seitz (WS) cell around a lattice point is
defined as the locus of points in space that are closer to
that lattice point than to any of the other lattice points.
NANO 106 - Crystallography of Materials by Shyue Ping Ong - Lecture 1
The WS cell
• is a unit cell, i.e., tiles
space to reproduce the
lattice;
• can have more than 4
sides in 2D and more
than 6 sides in 3D;
• Preserves symmetry of
net/lattice.