Presentation is loading. Please wait.

Presentation is loading. Please wait.

Solid State Physics Yuanxu Wang School of Physics and Electronics Henan University 双语教学示范课程.

Published byCamron Hancock Modified over 8 years ago

Similar presentations

Presentation on theme: "Solid State Physics Yuanxu Wang School of Physics and Electronics Henan University 双语教学示范课程."— Presentation transcript:

1 Solid State Physics Yuanxu Wang School of Physics and Electronics Henan University wyxhenu@gmail.com 双语教学示范课程

2 Page  2 Why does not exist fivefold axis? The crystal periodicity and translation symmetry. Quasicrystal : Long-range orientation, no long-range translation symmetry §1.6 Symmetry Operation  Fivefold axis?

3 Page  3 Why does not exist fivefold axis? A and B are nearest points of O. Array A’B’ are certainly parallel to array AB Thus, m is integer number Consequently

4 Page  4 The physical constants of a crystal is strongly depended on its symmetry. Such as dielectric constant, piezoelectric constant, elastic constant Application of symmetry operation  Dielectric constant and symmetry Applying matrix of symmetry operation, then The dielectric constant should be unchanged with symmetry operating.

5 Page  5 1) Applying the rotating 90 degree along x (a) axis 2) Applying the rotating 90 degree along y (a) axis 3) Applying (1.22), we can obtain (1.22) (1.23) (1.24)

6 Page  6 3) Applying (1.24) to (1.23), we obtain (1.24)  Thus, the number of the individual dielectric constants for a cubic crystal is only one. Mention: the symmetry is very important for the properties of crystals.

7 Page  7 §7 Classification of crystal structure According to the crystal cell Cubic Tetragonal Triclinic Monoclinic Hexagonal Trigonal orthorhombic According to the function electric conductor semiconductor Insulator Magnetic medium Dielectric Superconductor According the mode of combination Molecular crystals Ionic crystals Covalent crystals Metallic crystal Hydrogen bond crystal

8 Page  8 CrystalFeaturesBravais lattice The point group (international symbol) Triclinica ≠b ≠c a ≠b ≠g simple triclinic(Without shaft) Neither the symmetry axis nor the symmetry plane Monoclinica ≠b ≠c a = b = 90° ≠g Simple monoclinic;Bsae- centered monoclinic One C2, mirror symmetry Orthorhombica ≠b ≠c a = b = g = 90° Simple orthogonal;Bsae- centered orthorhombic;Body- centered orthogonal;Face- centered orthogonal Three mutually perpendicular C2 Trigonal a = b = c a = b = g ≠90° TrigonalOne C3 Tetragonala = b ≠c a = b = g = 90° Simple tetragonal;Body- centered tetragonal one C4 Hexagonala = b ≠c a=b= 90°;g =120° Hexagonalone C6 Cubica = b = c a = b = g = 90° simple cubic; body- centered cubic; face-centered cubic Four C3

Download ppt "Solid State Physics Yuanxu Wang School of Physics and Electronics Henan University 双语教学示范课程."

Similar presentations

INTRODUCTION TO CERAMIC MINERALS

INTRODUCTION TO CERAMIC MINERALS
More on symmetry Learning Outcomes:

More on symmetry Learning Outcomes:
PX3012 The Solid State Course coordinator: Dr. J. Skakle CM3020 Solid State Chemistry Course coordinator: Dr. J. Feldmann.

PX3012 The Solid State Course coordinator: Dr. J. Skakle CM3020 Solid State Chemistry Course coordinator: Dr. J. Feldmann.
Solids Image:Wikimedia Commons User Alchemistry-hp.

Solids Image:Wikimedia Commons User Alchemistry-hp.
Fundamental Concepts Crystalline: Repeating/periodic array of atoms; each atom bonds to nearest neighbor atoms. Crystalline structure: Results in a lattice.

Fundamental Concepts Crystalline: Repeating/periodic array of atoms; each atom bonds to nearest neighbor atoms. Crystalline structure: Results in a lattice.
1. 2 3 4 5 t1 t2 6 t1 t2 7 8 t1 t2 9 t1 t2.

t1 t2 6 t1 t2 7 8 t1 t2 9 t1 t2.
Lesson 12—Working with Space Groups How to convert a space group to a point group Adding the translational elements Calculating the coordinates of the.

Lesson 12—Working with Space Groups How to convert a space group to a point group Adding the translational elements Calculating the coordinates of the.
Point Groups (Crystal Classes)

Point Groups (Crystal Classes)
Solids Image:Wikimedia Commons User Alchemistry-hp.

Solids Image:Wikimedia Commons User Alchemistry-hp.
III Crystal Symmetry 3-1 Symmetry elements (1) Rotation symmetry

III Crystal Symmetry 3-1 Symmetry elements (1) Rotation symmetry
VI. Reciprocal lattice 6-1. Definition of reciprocal lattice from a lattice with periodicities in real space Remind what we have learned in chapter.

VI. Reciprocal lattice 6-1. Definition of reciprocal lattice from a lattice with periodicities in real space Remind what we have learned in chapter.
Lecture 2: Crystal Symmetry

Lecture 2: Crystal Symmetry
Lec. (4,5) Miller Indices Z X Y (100).

Lec. (4,5) Miller Indices Z X Y (100).
Lecture IX Crystals dr hab. Ewa Popko. The Schrödinger equation The hydrogen atom The potential energy in spherical coordinates (The potential energy.

Lecture IX Crystals dr hab. Ewa Popko. The Schrödinger equation The hydrogen atom The potential energy in spherical coordinates (The potential energy.
Chapter 13 The Chemistry of Solids. Types of Solids Metals Network Ionic Molecular Amorphous.

Chapter 13 The Chemistry of Solids. Types of Solids Metals Network Ionic Molecular Amorphous.
ENE 311 Lecture 3. Bohr’s model Niels Bohr came out with a model for hydrogen atom from emission spectra experiments. The simplest Bohr’s model is that.

ENE 311 Lecture 3. Bohr’s model Niels Bohr came out with a model for hydrogen atom from emission spectra experiments. The simplest Bohr’s model is that.
© Oxford Instruments Analytical Limited 2001 MODULE 2 - Introduction to Basic Crystallography Bravais Lattices Crystal system Miller Indices Crystallographic.

© Oxford Instruments Analytical Limited 2001 MODULE 2 - Introduction to Basic Crystallography Bravais Lattices Crystal system Miller Indices Crystallographic.
CONDENSED MATTER PHYSICS PHYSICS PAPER A BSc. (III) (NM and CSc.) Harvinder Kaur Associate Professor in Physics PG.Govt College for Girls Sector -11, Chandigarh.

CONDENSED MATTER PHYSICS PHYSICS PAPER A BSc. (III) (NM and CSc.) Harvinder Kaur Associate Professor in Physics PG.Govt College for Girls Sector -11, Chandigarh.
Crystals and Symmetry. Why Is Symmetry Important? Identification of Materials Prediction of Atomic Structure Relation to Physical Properties –Optical.

Crystals and Symmetry. Why Is Symmetry Important? Identification of Materials Prediction of Atomic Structure Relation to Physical Properties –Optical.
Symmetry Elements II.

Symmetry Elements II.

Similar presentations

Ads by Google