Presentation is loading. Please wait.

Presentation is loading. Please wait.

1/12/2015PHY 752 Spring 2015 -- Lecture 11 PHY 752 Electrodynamics 11-11:50 AM MWF Olin 107 Plan for Lecture 1: Reading: Chapters 1-2 in Marder’s text.

Published byDaisy Crawford Modified over 9 years ago

Similar presentations

Presentation on theme: "1/12/2015PHY 752 Spring 2015 -- Lecture 11 PHY 752 Electrodynamics 11-11:50 AM MWF Olin 107 Plan for Lecture 1: Reading: Chapters 1-2 in Marder’s text."— Presentation transcript:

1 1/12/2015PHY 752 Spring 2015 -- Lecture 11 PHY 752 Electrodynamics 11-11:50 AM MWF Olin 107 Plan for Lecture 1: Reading: Chapters 1-2 in Marder’s text 1.Course structure and expectations 2.Crystal structures a.Real and reciprocal space lattice vectors b.Some examples c.Point symmetry properties d.Introduction to group theory

2 1/12/2015PHY 752 Spring 2015 -- Lecture 12 http://users.wfu.edu/natalie/s15phy752/

3 1/12/2015PHY 752 Spring 2015 -- Lecture 13

4 1/12/2015PHY 752 Spring 2015 -- Lecture 14

5 1/12/2015PHY 752 Spring 2015 -- Lecture 15 Course syllabus: In the formal portion of the course, the following topics are usually covered: Crystalline structures Translation vectors and reciprocal lattice vectors Symmetry properties of crystals; brief introduction to group theory analysis Brief survey of common structures and their properties X-ray and neutron scattering analysis of crystals Electronic structure analysis Simple model examples Linear combinations of atomic orbital analyses Hartree-Fock approximations Density functional formalism Numerical approximations and methods Surfaces and interfaces Relationship of interface and bulk properties Low energy electron diffraction analysis Scanning probe analysis of surfaces Defects and disorder effects

6 1/12/2015PHY 752 Spring 2015 -- Lecture 16 Course syllabus continued: Depending on time available the following additional formal topics are often covered: Mechanical properties of solids Cohesive properties Deformation properties Vibrational modes Dislocations and cracks Electronic transport in solids Semi-classical approximations and comparison with experiment Optical properties in solids Magnetic properties of solids  Feedback on topics choice appreciated.

7 1/12/2015PHY 752 Spring 2015 -- Lecture 17 Introduction to crystalline solids An ideal crystal fills all space o Limited possibilities for crystalline forms –  Only 14 Bravais lattices  Only 32 crystallographic point groups  Only 230 distinct crystallographic structures Quantitative descriptions of crystals in terms of lattice translations vectors and basis vectors Use of group theory in the study of crystal structures

8 1/12/2015PHY 752 Spring 2015 -- Lecture 18 Two-dimensional crystals

9 1/12/2015PHY 752 Spring 2015 -- Lecture 19 Some details – square lattice example

10 1/12/2015PHY 752 Spring 2015 -- Lecture 110 Energy associated with crystal configuration Simple pair potential models r

11 1/12/2015PHY 752 Spring 2015 -- Lecture 111 Energy of square lattice E(a) Note: This is the energy per atom assuming all atoms are identical.

12 1/12/2015PHY 752 Spring 2015 -- Lecture 112 Two-dimensional crystals -- continued

13 1/12/2015PHY 752 Spring 2015 -- Lecture 113 Two-dimensional crystals -- continued Honeycomb lattice (graphene sheet) Example of lattice with a “basis”

14 1/12/2015PHY 752 Spring 2015 -- Lecture 114 Honeycomb lattice (graphene sheet) a

15 1/12/2015PHY 752 Spring 2015 -- Lecture 115 “Conventional” versus “Primitive” unit cell

16 1/12/2015PHY 752 Spring 2015 -- Lecture 116 Wigner-Seitz cell Note that primitive cell and Wigner-Seitz cell have the same volume.

17 1/12/2015PHY 752 Spring 2015 -- Lecture 117 Generalization to 3-dimensions basis vector Bravais lattice

18 1/12/2015PHY 752 Spring 2015 -- Lecture 118 From http://web.mit.edu/6.730

19 1/12/2015PHY 752 Spring 2015 -- Lecture 119 Simple cubic lattice:

20 1/12/2015PHY 752 Spring 2015 -- Lecture 120 Face-centered cubic lattice

21 1/12/2015PHY 752 Spring 2015 -- Lecture 121 Body centered cubic lattice Wigner-Seitz cell

Download ppt "1/12/2015PHY 752 Spring 2015 -- Lecture 11 PHY 752 Electrodynamics 11-11:50 AM MWF Olin 107 Plan for Lecture 1: Reading: Chapters 1-2 in Marder’s text."

Similar presentations

Lattice Dynamics related to movement of atoms

Lattice Dynamics related to movement of atoms
Why Study Solid State Physics?

Why Study Solid State Physics?
Crystal Structure Continued!

Crystal Structure Continued!
Lecture 2.1 Crystalline Solids. Poly-crystalline solids - Grains Mono-crystalline solids- Whiskers, Wafers.

Lecture 2.1 Crystalline Solids. Poly-crystalline solids - Grains Mono-crystalline solids- Whiskers, Wafers.
II. Crystal Structure Lattice, Basis, and the Unit Cell

II. Crystal Structure Lattice, Basis, and the Unit Cell
Lattice Dynamics related to movement of atoms

Lattice Dynamics related to movement of atoms
Crystal Structure Continued! NOTE!! Again, much discussion & many figures in what follows was constructed from lectures posted on the web by Prof. Beşire.

Crystal Structure Continued! NOTE!! Again, much discussion & many figures in what follows was constructed from lectures posted on the web by Prof. Beşire.
Wigner-Seitz Cell The Wigner–Seitz cell around a lattice point is defined as the locus of points in space that are closer to that lattice point than to.

Wigner-Seitz Cell The Wigner–Seitz cell around a lattice point is defined as the locus of points in space that are closer to that lattice point than to.
Solid State Physics 2. X-ray Diffraction 4/15/2017.

Solid State Physics 2. X-ray Diffraction 4/15/2017.
Solid State Physics (1) Phys3710

Solid State Physics (1) Phys3710
1/14/2015PHY 752 Spring 2015 -- Lecture 21 PHY 752 Electrodynamics 9-9:50 AM MWF Olin 107 Plan for Lecture 2: Reading: Chapter 1 & 2 in MPM; Crystal structures.

1/14/2015PHY 752 Spring Lecture 21 PHY 752 Electrodynamics 9-9:50 AM MWF Olin 107 Plan for Lecture 2: Reading: Chapter 1 & 2 in MPM; Crystal structures.
A Brief Description of the Crystallographic Experiment

A Brief Description of the Crystallographic Experiment
PHYS3004 Crystalline Solids

PHYS3004 Crystalline Solids
02/03/2014PHY 712 Spring 2014 -- Lecture 81 PHY 712 Electrodynamics 10-10:50 AM MWF Olin 107 Plan for Lecture 8: Start reading Chapter 4 Multipole moment.

02/03/2014PHY 712 Spring Lecture 81 PHY 712 Electrodynamics 10-10:50 AM MWF Olin 107 Plan for Lecture 8: Start reading Chapter 4 Multipole moment.
4/15/2015PHY 752 Spring 2015 -- Lecture 321 PHY 752 Solid State Physics 11-11:50 AM MWF Olin 107 Plan for Lecture 32:  The Hubbard model  Motivation.

4/15/2015PHY 752 Spring Lecture 321 PHY 752 Solid State Physics 11-11:50 AM MWF Olin 107 Plan for Lecture 32:  The Hubbard model  Motivation.
PH 0101 UNIT 4 LECTURE 1 INTRODUCTION TO CRYSTAL PHYSICS

PH 0101 UNIT 4 LECTURE 1 INTRODUCTION TO CRYSTAL PHYSICS
X. Low energy electron diffraction (LEED)

X. Low energy electron diffraction (LEED)
1 Crystalline Nature of Solids 01 Mar, 2006. 2 Crystalline Nature of Solids.

1 Crystalline Nature of Solids 01 Mar, Crystalline Nature of Solids.
EEE539 Solid State Electronics 1. Crystal Structure Issues that are addressed in this chapter include:  Periodic array of atoms  Fundamental types of.

EEE539 Solid State Electronics 1. Crystal Structure Issues that are addressed in this chapter include:  Periodic array of atoms  Fundamental types of.
Review of Semiconductor Physics Solid-state physics The daunting task of solid state physics Quantum mechanics gives us the fundamental equation The equations.

Review of Semiconductor Physics Solid-state physics The daunting task of solid state physics Quantum mechanics gives us the fundamental equation The equations.

Similar presentations

Ads by Google