2016 Fundamentals of Electronic Materials

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Academic unit or major
Graduate major in Electrical and Electronic Engineering
Instructor(s)
Nakagawa Shigeki  Sugahara Satoshi 
Course component(s)
Lecture
Day/Period(Room No.)
Mon7-8(S222)  Thr7-8(S222)  
Group
-
Course number
EEE.D401
Credits
2
Academic year
2016
Offered quarter
1Q
Syllabus updated
2016/4/27
Lecture notes updated
2016/4/8
Language used
English
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Course description and aims

Properties of electrons in solids are the basis of all the electronic materials and electron devices. This course provides fundamental treatment to understand the electron's behaviors in solids based on the solid state physics.
Beginning with a brief review of fundamental quantum mechanics, some perturbation theories will be lectured to understand electron states in various potentials where the analytical solution of Schrodinger equation is hard to be obtained.
In order to treat electrons in solids, the electrons should be regarded as waves. We will see that carrier electrons can be treated as waves which propagate in the solids, and which cause scattering and diffraction. Furthermore, it is recognized that an energy band will be formed if a periodic perturbation potential is applied to nearly free electron model, which is the basis to treat carrier electrons in metals and semiconductors.
More precise band calculations based on the Bloch’s theorem and tight binding approximation will be lectured in order to understand more specific band structure of the important crystals, such as diamond zinc-blend crystals. Precise discussion about electron states in k-space in the band structures will be given to understand the electron properties in such crystals
Furthermore, the relationship between band structures and space symmetries will be lectured to apply space group theory to calculations and understanding of the band structures.

Student learning outcomes

1. Understanding of fundamental quantum mechanics and some perturbation theories for various potentials where the analytical solution is hard to be obtained.
2. Treatment to regard carrier electrons as propagating waves, which cause scattering and diffraction.
3. Energy band will be formed if a periodic perturbation potential is applied to a nearly free electron model.
4. Precise band calculations based on the Bloch’s theorem and a tight binding approximation method.
5. Band structures of diamond and zinc-blend structures.
6. Precise discussion about electron states in k-space of the band structures.
7. Understanding of a relationship between the band structure and the space symmetry.

Keywords

Quantum mechanics, Perturbation theory, Solid state physics, periodic potential, Energy band, Bloch's wave, Band structure, Symmetry and group theory

Competencies that will be developed

Intercultural skills Communication skills Specialist skills Critical thinking skills Practical and/or problem-solving skills
- - -

Class flow

Exercises are carried out after every lecture in the class to help students understand.

Course schedule/Required learning

  Course schedule Required learning
Class 1 Review of quantum mechanics I Basis of quantum mechanics, Schrodinger equation, properties of wave functions, operator, steady states, degenerate and non-degenerated states
Class 2 Review of quantum mechanics II Hermitian operator, Completeness of wave functions, vector representation of state, matrix representation of operators, Dirac notation, orthogonalization and unitary transformation.
Class 3 Time-independent perturbation theory - Non degenerated system- Time-independent perturbation theory for non-degenerated system.
Class 4 Time-independent perturbation theory and matrix elements Time-independent perturbation theory and relationship with matrix elements, Stark effect, etc.
Class 5 Time-independent perturbation theory - Degenerated system- Time-independent perturbation theory for degenerated system.
Class 6 Time-dependent perturbation theory Time-dependent perturbation theory for non-degenerated system. Transition of states and selection rule.
Class 7 Absorption and emission of light using time dependent perturbation theory Absorption and emission of light using time dependent perturbation theory. Transition probability, golden rule,
Class 8 Basis of waves in solid -propagation, scattering and diffraction- Basis to treat particles as waves in solid -propagation, scattering and diffraction-
Class 9 Free electron model of solids Bloch's theorem, Brillouin zone, and empty lattice model for band theory
Class 10 Nearly free electron model of solids Perturbation theory for periodic potential and generation of bandgap
Class 11 Tight binding theory Chemical bond, Bloch sum, and tight-binding band theory for simple systems
Class 12 Tight binding Hamiltonian How to create tight-binding Hamiltonian for solids
Class 13 Band structures of semiconductors Calculation of band structures of diamond and zinc-blend semiconductors, and chemical trend of the band structures
Class 14 対称性と群論 Irreducible representation and character tables
Class 15 Application of group theory to band structures Understanding band structures from the point of view of symmetry

Textbook(s)

Course materials will be provided from OCW-i

Reference books, course materials, etc.

Course materials will be provided from OCW-i
C.Kittel : "Introduction to Solid State Physics," John Wiley & Sons, Inc.
H.Ibach and H.Lute : "Solid-State Physics," Springer-Verlag
Takeo Fujiwara: "Kotai-denshi-bussei-ron"(Japanese), Uchidaroukakuho

Assessment criteria and methods

Evaluation will be based on the exercises done in classes (40%) and a term-end examination (60%).

Related courses

  • EEE.D411 : Semiconductor Physics
  • EEE.D511 : Magnetic Property and Spin Dependent Phenomenon
  • EEE.D501 : Dielectirc Property and Organic Devices
  • EEE.D431 : Fundamentals of Light and Matter I
  • EEE.D531 : Fundamentals of Light and Matter IIa
  • EEE.D532 : Fundamentals of Light and Matter IIb
  • EEE.D533 : Fundamentals of Light and Matter IIc
  • EEE.D421 : Imaging Materials
  • EEE.D551 : Nano-Structure Devices

Prerequisites (i.e., required knowledge, skills, courses, etc.)

Knowledge of fundamentals on quantum mechanics.

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