LABORATORY OF PHYSICS OF MATERIALS

The laboratory consists of a series of experiences with a duration of two or three afternoons each, focusing mainly on the properties of semiconductor materials. The purpose of the experiences is mostly to develop a critical sense and autonomy in the process of measuring the physical properties of the materials. Experiences include:

• the Hall measurement of electrical and doping properties of semiconductors;
• voltage-current characteristics of a p-n junction;
• measurement of absorption and reflection properties;
• measurement of the efficiency of photovoltaic cells as a function of the wavelength of the incident light;
• life time measurements of photo-excited carriers.

PHYSICS OF MATERIALS

Crystal Structures

• General Description of Crystal Structures
• Some Important Crystal Structures
• Cubic Structures
• Close-Packed Structures
• Structures of Covalently Bonded Solids
• Crystal Structure Determination

X-Ray Diffraction

• Bragg Theory
• Lattice Planes and Miller Indices
• General Diffraction Theory
• The Reciprocal Lattice
• The Meaning of the Reciprocal Lattice
• X-Ray Diffraction from Periodic Structures
• The Ewald Construction
• Relation Between Bragg and Laue Theory

Bonding in Solids

• Attractive and Repulsive Forces
• Ionic Bonding
• Covalent Bonding
• Metallic Bonding
• Hydrogen Bonding
• van derWaals Bonding

Mechanical Properties

• Elastic Deformation
• Macroscopic Picture
• Elastic Constants
• Poisson’s Ratio
• Relation between Elastic Constants
• Microscopic Picture
• Plastic Deformation
• Estimate of the Yield Stress
• Point Defects and Dislocations
• The Role of Defects in Plastic Deformation
• Fracture

Thermal Properties of the Lattice

• Lattice Vibrations
• A Simple Harmonic Oscillator
• An Infinite Chain of Atoms
• One Atom Per Unit Cell
• The First Brillouin Zone
• Two Atoms per Unit Cell
• A Finite Chain of Atoms
• Quantized Vibrations, Phonons
• Three-Dimensional Solids
• Generalization to Three Dimensions
• Estimate of the Vibrational Frequencies from the Elastic Constants
• Heat Capacity of the Lattice
• ClassicalTheory and Experimental Results
• Einstein Model
• Debye Model
• Thermal Conductivity
• Thermal Expansion
• Allotropic Phase Transitions and Melting

Electronic Properties of Metals: Classical Approach

• Basic Assumptions of the Drude Model
• Results from the Drude Model
• DC Electrical Conductivity
• Hall Effect
• Optical Reflectivity of Metals
• TheWiedemann–Franz Law
• Shortcomings of the Drude Model

Electronic Properties of Solids: Quantum Mechanical Approach

• The Idea of Energy Bands
• Free Electron Model
• The Quantum Mechanical Eigenstates
• Electronic Heat Capacity
• The Wiedemann–Franz Law
• The General Form of the Electronic States
• Nearly Free Electron Model
• Energy Bands in Real Solids
• Transport Properties

Semiconductors

• Intrinsic Semiconductors
• Temperature Dependence of the Carrier Density
• Doped Semiconductors
• n and p Doping
• Carrier Density
• Conductivity of Semiconductors
• Semiconductor Devices
• The pn Junction
• Transistors
• Optoelectronic Devices

Magnetism

• Macroscopic Description
• Quantum Mechanical Description of Magnetism
• Paramagnetism and Diamagnetism in Atoms
• Weak Magnetism in Solids
• Diamagnetic Contributions
• Contribution from the Atoms
• Contribution from the Free Electrons
• Paramagnetic Contributions
• Curie Paramagnetism
• Pauli Paramagnetism
• Magnetic Ordering
• Magnetic Ordering and the Exchange Interaction
• Magnetic Ordering for Localized Spins
• Magnetic Ordering in a Band Picture
• Ferromagnetic Domains
• Hysteresis

Dielectrics

• Macroscopic Description
• Microscopic Polarization
• The Local Field
• Frequency Dependence of the Dielectric Constant
• Excitation of Lattice Vibrations
• Electronic Transitions
• Impurities in Dielectrics
• Ferroelectricity
• Piezoelectricity
• Dielectric Breakdown