Slide 1 Lecture 1

Introduction to Solid State Physics

PY3PO3

Prof. Igor Shvets ivchvets@tcd.ie

Slide 2 Lecture 1

Lattice structure: lattice with a basis.

Lattice structures of common chemical elements.

Concept of Bravais lattice, definition and examples.

Primitive vectors of Bravais lattice.

Coordination number.

Primitive/Conventional unit cell.

Wigner-Seitz primitive cell.

Examples of common crystal structures.

Body-centered cubic lattice.

Face-centered cubic lattice.

Crystal systems

Reciprocal lattice.

First Brillouin zone.

Lattice planes and Miller indices.

Syllabus

Slide 3 Lecture 1

Determination of crystal structures by X-ray diffraction.

Bragg formulation of X-ray diffraction by a crystal.

Von Laue formulation of X-ray diffraction by a crystal.

Equivalence of Bragg and Von Laue formulations.

Diffractometers

Symmetry, elements of point groups

Geometrical structure factor.

Atomic form factor.

Crystal defects.

Points defects

Line defects

Stress and Strain.

Syllabus

Slide 4 Lecture 1

Solid State Physics ~ Ashcroft & Mermin, [Holt-Saunders]

• A great text for anyone with an interest in the subject.

Solid State Physics ~ Hook & Hall, [Wiley]

• Useful text. Read as a compliment to Ashcroft or Elliott.

Introduction To Solid State Physics ~ Kittel, [Wiley]

• Covers a huge amount in basic detail.

The Physics and Chemistry of Solids ~ Elliott, [Wiley]

• Lateral reading. Quite Chemistry based. Good for problem solving.

Structure of materials ~ De Graef, McHenry,

[Cambridge]

• Covers a huge amount in basic detail, good for problem solving.

Recommended Reading

Slide 5 Lecture 1

Crystals

Solids can be categorised into either crystalline or non-

crystalline solids.

This course deals with the structures found in crystalline

solids i.e. crystals.

A Crystal is a solid in which the

constituent atoms, molecules,

or ions are packed in a

regularly ordered, repeating

pattern extending in all three

spatial dimensions.

Gallium Crystal

Slide 6 Lecture 1

Despite an underlying crystalline

structure the crystal itself may

not appear regular in shape.

A closer look at the

substance reveals a

repeating pattern.

Crystals

Slide 7 Lecture 1

Silicon (Si)

Examples

Principle component of

most semiconductors

Structure

Diamond Cubic.

More on that later

Slide 8 Lecture 1

Crystalline SiO2

Silicon Dioxide or Silica with a

definite crystalline structure.

Structure

Each Silicon atom is surrounded

by four Oxygen atoms.

Silicon Dioxide is an example of

Tetrahedral oxygen termination.

Oxidation State Electron

Configuration

O -2 [He].2s2.2p

6

Si 4 [Ne]

Examples

Slide 9 Lecture 1

Structure

As with the crystalline SiO2

- Most silicon atoms have 4

bonds.

- Most oxygen atoms have 2

bonds.

Amorphous SiO2

(Silica gel)

Silica gel is an example of a non-

crystalline solid.

The local symmetry is the same

as the crystalline SiO2

However, translational symmetry

is missing.

Examples

Slide 10 Lecture 1

Oxygen Termination

The two forms of oxygen termination are Tetrahedral and

Octahedral

These refer to the structure of the oxide in relation to the original

structure of the crystal.

Tetrahedral Oxygen termination

is when four oxygen atoms

create a tetrahedron around the

original atom e.g. Silicon

Octahedral Oxygen termination

is when six oxygen atoms create

a octahedron around the original

atom e.g. Aluminium

Slide 11 Lecture 1

Oxidation

State

Electron

Configuration

O -2 [He].2s2.2p

6

Al 3 [Ne]

Aluminium Oxide (Al2O

3)

Structure

Each Aluminium atom is

surrounded by six Oxygen

atoms.

Aluminium Oxide is an

example of Octahedral oxygen

termination.

Examples

Slide 12 Lecture 1

Magnesium Oxide (MgO)

Oxidation State Electron Configuration

O -2 [He].2s2.2p

6

Mg 2 [Ne]

Structure

Structure is the same as

that of Sodium Chloride.

i.e. F.C.C. lattice with a two

point basis

Again more on that later

Examples

Slide 13 Lecture 1

32 oxygen anions form an F.C.C. lattice

8 tetrahedral interstices are occupied

by Fe3+

ions

Magnetite ( Fe3O

4)

16 octahedral interstices are occupied by

Fe3+

and Fe2+

ions in equal proportions

This is an example

of Spinel structure.

Lattice constant

(Basic repeat unit)

a = 0.8397nm

Examples

a a

Slide 14 Lecture 1

Spinel Group

Refers to a class of minerals with the general formulation

A2+

B2

3+O

4

2-

The oxide anions arrange in a cubic lattice with the A and B

cations occupying the Tetrahedral and Octahedral sites.

Possibilities for A and B include Magnesium, Zinc, Iron,

Manganese, Aluminium, Chromium, Titanium and Silicon.

In the case of Magnetite (Fe3O

4) the Iron is both A and B. That is,

A and B are the same metal under different charges.

Fe3+

(Fe2+

Fe3+

)O4

2-

Slide 15 Lecture 1

High Performance Materials

The majority of the worlds electricity supply is generated in

power stations using steam turbines.

Through the use of coal,

nuclear power, etc.

steam is generated and

is passed through the

giant steam turbines.

The turbines rotate and

generate electricity.

2

11

T

T

Assuming the system can be considered

a Carnot Engine and using current

average values of temperatures in the

system (T1=35°C and T

2=540°C) the

efficiency is calculated to be 62%.

Slide 16 Lecture 1

High Performance Materials

As supplies of fossil fuels are

diminishing, there is large interest

in making the steam turbine a

more efficient process for

generating electricity.

A way to increase this efficiency

is to operate the system with a

larger temperature gap, ie by

making T2

larger.

Slide 17 Lecture 1

High Performance Materials

2

11

T

T

This is not as simple as it sounds. To

increase the efficiency by just 5% would

require an average operating temperature

increase from 540°C to 660°C.

The turbine blades themselves must be able

to withstand these high temperatures

without melting or buckling.

This is where knowledge of the crystal structure of

the materials used in their production is

invaluable. Without a detailed analysis of the

structure engineers and scientists would not be

able to combat the problem of creating a more

efficient system.

Slide 18 Lecture 1

Lattice

A Lattice is a regular, periodic

array of points throughout an area

(2D) or a space (3D).

This picture shows one of many

possible lattice types.

When dealing with crystal structures it is best to firstly

consider the mathematical idea of a lattice, without the

notion of atoms or molecules at this stage.

Example of a 2D Lattice

IMPORTANT NOTE: The lattice is the underlying pattern of

the crystal. The crystal is being described by the lattice

that can contain more than one atom/ion assigned to

each point of the lattice. This is called a Basis.

Slide 19 Lecture 1

Basis

You have a lattice

with more than one

atom/ion assigned to

each lattice point.

Atoms can be the

same or different.

Complex structures

will have larger/more

complex bases.

All crystal structure

consists of identical

copies of the same

physical unit, called

the basis, assigned

to all the points of

the lattice.

Consider a point of the lattice

Now introduce a arbitrary basis of two atomsThen apply to the rest of the lattice

Lattice + Basis = Crystal

Slide 20 Lecture 1

While the basis is

assigned to each point

of the lattice there is

nothing to say that it is

anywhere near this

point.

Consider the same

lattice and basis as

before.

Basis

Increase the separation

between the basis and

the lattice point.

We discover that the

same lattice is revealed

when the new position

of the basis is applied

to each lattice point.

Slide 21 Lecture 1

However, there is no

unique choice of Basis!

Even the most complex

crystal structures can be

broken down into a

lattice and a basis.

Basis

Lattice + Basis =

Crystal

Each of these Basis,

when combined with

this lattice, will yield

the same crystal.

Slide 22 Lecture 1

Symmetry of a Basis

Consider a Basis that is itself symmetric and combine with the

lattice to create a simple crystal structure;

Crystal properties

considered along

the x-axis are

independent of

direction (left or

right)…

… they are also

independent of

direction along the

y-axis (up or

down).

Slide 23 Lecture 1

Now consider a basis that is not completely symmetric;

Crystal properties

considered along

the x-axis are

independent of

direction (left or

right)…

… However the

structure now has a

lower symmetry

than before and is

not the same from

the top and

bottom.

Symmetry of a Basis

Slide 24 Lecture 1

What if the basis is completely asymmetric?

The properties of

the substance may

no longer be

independent of

direction they are

measured.

Symmetry of a Basis

Slide 25 Lecture 1

Bravais Lattice

The foundation of ANY Crystal structure is the Bravais lattice.

Definitions of Bravais Lattice

The vectors used to define a Bravais lattice,

a1, a

2, a

3 ,are called the primitive vectors.

1. Infinite array of discrete points that appear exactly

the same from whichever of the points the array is viewed.

2. All the points with position vectors

R = n1a

1+ n

2a

2+ n

3a

3

Where; a1, a

2, a

3 are three vectors not all in the same plane

and n1, n

2 , n

3 are integer values.

3. A discrete set of vectors, not all in the same plane, closed

under vector addition or subtraction.

Slide 26 Lecture 1

One of the most common three-

dimensional Cubic Bravais

lattices, the Simple Cubic lattice.

All a1, a

2, a

3 ,are of equal length

and orthogonal.

a1

a2

a3

Pictured: A general two-dimensional

Bravais lattice of no particular symmetry.

The vectors a1

and a2

are primitive

vectors.

Bravais Lattice

Slide 27 Lecture 1

Non-Bravais Lattices

Using the first definition of a Bravais lattice

it is clear that the 2D Honeycomb Structure

is not a Bravais lattice.

The lattice does not appear exactly same

when viewed from P, Q and RP R

Q

In 3D an example of a non-

Bravais lattice is the Hexagonal

Close-Packed structure.

The points of the middle layer

are above the centres of the

triangles in the layer below. E.g.

if you double the vector from

corner point to centre point, you

will NOT arrive to another point

of the lattice.

Slide 28 Lecture 1

2D Non-Bravais Lattice with a Basis

All Non-Bravais lattices

can be created from a

Bravais lattice with a

basis.

The red points form a

simple 2D bravais lattice.

Adding a two-point basis

to each lattice point…

and it starts to look

familiar.

So if we go back to the case of Honeycomb structure. While it

itself is not a Bravais lattice, it can be considered to be a Bravais

lattice with a two-point basis.

Slide 29 Lecture 1

As mentioned before, the choice of basis is not unique, there are

infinitely many bases to choose from. However, that does not

mean all combinations of two points will work…

Consider a lattice point

and the basis shown.

Apply this basis to the

same lattice as before.

If we super-impose the

picture of the honeycomb

over ours it is obvious

that they do not match.

2D Non-Bravais Lattice with a Basis

Slide 30 Lecture 1

In each of the following cases indicate whether the structure is a

Bravais lattice.

a) Base-centered Cubic (Simple cubic with additional points in the

centres of the horizontal faces [2])

b) Side-centered Cubic (Simple cubic with additional points in the

centres of the vertical faces [4])

c) Edge-centered Cubic (Simple cubic with additional points at the

midpoints of the lines joining the simple cubic points [12])

Exercise

If it is a Bravais lattice give three primitive vectors.

If not describe it as Bravais with the smallest possible basis.

a) b) c)

Slide 31 Lecture 1

Questions/Problems

What is a Crystal?

What is a Bravais Lattice?

What is a Basis?

What is meant by the Symmetry of a basis?

I would urge you to know the answers to these questions before

next time.

Good resources

Solid State Physics ~ Ashcroft, Ch. 4

Introduction to Solid State Physics ~ Kittel, Ch. 1

The Physics and Chemistry of Solids ~ Elliott, Ch. 2

Solid State Physics ~ Hook & Hall, Ch. 1