Primitive cells, Wigner-Seitz cells, and 2D lattices. 4P70, Solid State Physics Chris Wiebe

Similar documents
Introduction to Solid State Physics

CRYSTAL LATTICE. Defining lattice: Mathematical construct; ideally infinite arrangement of points in space.

General Objective. To develop the knowledge of crystal structure and their properties.

Crystallography. Duration: three weeks (8 to 9 hours) One problem set. Outline: 1- Bravais Lattice and Primitive

Chapter 1. Crystal Structure

Two dimensional Bravais lattices

بسم هللا الرحمن الرحیم. Materials Science. Chapter 3 Structures of Metals & Ceramics

Analytical Methods for Materials

Solid State Physics 460- Lecture 2a Structure of Crystals (Kittel Ch. 1)

Solid State Device Fundamentals

Chapter One: The Structure of Metals

Fundamental concepts and language Unit cells Crystal structures! Face-centered cubic! Body-centered cubic! Hexagonal close-packed Close packed

3D 14 BRAVAIS LATTICES AND THE SEVEN CRYSTAL SYSTEM

Crystal structure of the material :- the manner in which atoms, ions, or molecules are spatially.

Schematic Interpretation of Anomalies in the Physical Properties of Eu and Yb Among the Lanthanides

(iii) Describe how you would use a powder diffraction pattern of this material to measure

Physics of Materials: Symmetry and Bravais Lattice To understand Crystal Plane/Face. Dr. Anurag Srivastava

Chapter-3 MSE-201-R. Prof. Dr. Altan Türkeli

ECE440 Nanoelectronics. Lecture 08 Review of Solid State Physics

Review key concepts from last lecture (lattice + basis = unit cell) Bravais lattices Important crystal structures Intro to miller indices

Chapter Outline How do atoms arrange themselves to form solids?

Packing of atoms in solids

Topic 2-1: Lattice and Basis Kittel Pages: 2-9

Energy and Packing. typical neighbor bond energy. typical neighbor bond energy. Dense, regular-packed structures tend to have lower energy.

Structure of silica glasses (Chapter 12)

UNIT V -CRYSTAL STRUCTURE

Li Mass = 7 amu Melting point C Density 0.53 g/cm 3 Color: silvery

Introduction to Engineering Materials ENGR2000 Chapter 3: The Structure of Crystalline Solids. Dr. Coates

Ex: NaCl. Ironically Bonded Solid

Chapter 8: Molecules and Materials

Materials Science and Engineering

Chapter1: Crystal Structure 1

9/16/ :30 PM. Chapter 3. The structure of crystalline solids. Mohammad Suliman Abuhaiba, Ph.D., PE

Symmetry in crystalline solids.

Basic Solid State Chemistry, 2 nd ed. West, A. R.

Chapter Outline. How do atoms arrange themselves to form solids?

CHAPTER 3. Crystal Structures and Crystal Geometry 3-1

Materials Science ME 274. Dr Yehia M. Youssef. Materials Science. Copyright YM Youssef, 4-Oct-10

Crystal Structure. Insulin crystals. quartz. Gallium crystals. Atoms are arranged in a periodic pattern in a crystal.

Single vs Polycrystals

STATE OF SOLIDIFICATION & CRYSTAL STRUCTURE

Fundamentals of Crystalline State and Crystal Lattice p. 1 Crystalline State p. 2 Crystal Lattice and Unit Cell p. 4 Shape of the Unit Cell p.

Figure.1. The conventional unit cells (thick black outline) of the 14 Bravais lattices. [crystallographic symmetry] 1

CHAPTER 3: SYMMETRY AND GROUPS, AND CRYSTAL STRUCTURES. Sarah Lambart

EP 364 SOLID STATE PHYSICS. Prof. Dr. Beşire Gönül. Course Coordinator

MME 2001 MATERIALS SCIENCE

Solid State Device Fundamentals

9/29/2014 8:52 PM. Chapter 3. The structure of crystalline solids. Dr. Mohammad Abuhaiba, PE

9/28/2013 9:26 PM. Chapter 3. The structure of crystalline solids. Dr. Mohammad Abuhaiba, PE

CRYSTAL STRUCTURE TERMS

ENGINEERING MATERIALS LECTURE #4

ASE324: Aerospace Materials Laboratory

Lectures on: Introduction to and fundamentals of discrete dislocations and dislocation dynamics. Theoretical concepts and computational methods

The structures of pure metals are crystalline (crystal lattice) with regular arrangement of metal atoms that are identical perfect spheres.

Example: Compute the wavelength of a 1 [kg] block moving at 1000 [m/s].

MSE420/514: Session 1. Crystallography & Crystal Structure. (Review) Amaneh Tasooji

Energy and Packing. Materials and Packing

Chem 253, UC, Berkeley. Chem 253, UC, Berkeley

Chapter 3: Atomic and Ionic Arrangements. Chapter 3: Atomic and Ionic Arrangements Cengage Learning Engineering. All Rights Reserved.


How can we describe a crystal?

Now, let s examine how atoms are affected as liquids transform into solids.

Semiconductor Physics

Families on the Periodic Table

Solids. The difference between crystalline and non-crystalline materials is in the extent of ordering

Lecture 2a - Structure of crystals - continued

Analytical Methods for Materials

Crystal Structures of Interest

New Materials from Mathematics Real and Imagined

Condensed Matter in a Nutshell

Diffusion & Crystal Structure

416 Solid State Physics ; Introduction & Overview

Chapter 3 Structure of Crystalline Solids

Condensed Matter Physics Prof. G.Rangarajan Department of Physics Indian Institute of Technology, Madras

MSE 170 Midterm review

Work hard. Be nice. Name: Period: Date: UNIT 2: Atomic Concepts Lesson 1: Give me an element, any element

Carbon nanostructures. (

3.40 Sketch within a cubic unit cell the following planes: (a) (01 1 ) (b) (112 ) (c) (102 ) (d) (13 1) Solution

CH445/545 Winter 2008

CHAPTER 5 IMPERFECTIONS IN SOLIDS PROBLEM SOLUTIONS ev /atom = exp. kt ( =

Chemistry*120* * Name:! Rio*Hondo*College* * * EXAMPLE*EXAM*1*!

Chapter 10. Liquids and Solids

These metal centres interact through metallic bonding

Chem 241. Lecture 19. UMass Amherst Biochemistry... Teaching Initiative

Twins & Dislocations in HCP Textbook & Paper Reviews. Cindy Smith

SCOPE OF ACCREDITATION TO ISO/IEC 17025:2005

CHAPTER 5 IMPERFECTIONS IN SOLIDS PROBLEM SOLUTIONS

Problems. 104 CHAPTER 3 Atomic and Ionic Arrangements

Structure factors and crystal stacking

CLASS TEST GRADE 11. PHYSICAL SCIENCES: CHEMISTRY Test 7: Chemical systems

Point Defects in Metals

Metallic crystal structures The atomic bonding is metallic and thus non-directional in nature

Point coordinates. Point coordinates for unit cell center are. Point coordinates for unit cell corner are 111

Where do we start? ocreate the Universe oform the Earth and elements omove the elements into their correct positions obuild the atmosphere and oceans

Evidence of Performance regarding the requirements for float glass according to EN 572

New Materials from Mathematics Real and Imagined

VI. THE STRUCTURE OF SOLIDS

E3 Redox: Transferring electrons. Session one of two First hour: Discussion (E1) 2nd and 3rd hour: Lab (E3, Parts 1 and 2A)

Two marks questions and answers. 1. what is a Crystal? (or) What are crystalline materials? Give examples

LAB II CRYSTAL STRUCTURE AND CRYSTAL GROWTH PART 1: CRYSTAL GROWTH. I. Introduction

Transcription:

Primitive cells, Wigner-Seitz cells, and 2D lattices 4P70, Solid State Physics Chris Wiebe

Choice of primitive cells! Which unit cell is a good choice?! A, B, and C are primitive unit cells. Why?! D, E, and F are not. Why?! Notice: the volumes of A, B, and C are the same. Also, the choice of origin is different, but it doesn t matter! Also: There is only one lattice point in the primitive unit cells.

Wigner-Seitz cells! How can we choose primitive cells?! One algorithm is the Wigner- Seitz cell! Steps: (1) Draw lines to connect a given lattice point to all nearby lattice points! (2) At the midpoint and normal to these lines, draw new lines (or planes in 3D)! (3) The smallest volume enclosed in this way is the Wigner-Seitz primitive cell Wigner-Seitz cell

Finding Wigner-Seitz cells (M. C. Escher) Phopholipid bilayers (P. C. Mason et al, PRE, 63, 030902 (2001)) Homework: What are the Wigner-Seitz cells for these lattices?

Fundamental types of lattices! Crystal lattices can be mapped into themselves by the lattice translations T, and by other symmetry operations! Physicists use the symmetry of the unit cells to classify crystal structures and how they fill space.! In this course, you will not have to know how this is done (this involves the use of point operations and translation operators)! However, you do have to understand how we classify lattices! In 2D, there are only 5 distinct lattices. These are defined by how you can rotate the cell contents (and get the same cell back), and if there are any mirror planes within the cell.! From now on, we will call these distinct lattice types Bravais lattices.! Unit cells made of these 5 types in 2D can fill space. All other ones cannot. π We can fill space with a rectangular lattice by 180 o rotations (not 90 o why?) π/3 We can fill space with a hexagonal lattice by 60 o rotations Note: this is the primitive cell of a hexagonal lattice (why? See Kittel, fig 9b)

Fivefold rotations and quasicrystals! It turns out that mathematicians discovered that you can only fill space by using rotations of unit cells by 2π, 2π/2, 2π/3, 2π/4, and 2π/6 radians (or, by 360 o, 180 o, 120 o, 90 o, and 60 0 )! But, rotations of the kind 2π/5 or 2π/7 do not fill space!! A quasicrystal is a quasiperiodic nonrandom assembly of two types of figures (since we need two types, it is not a Bravais lattice you cannot fill space with just one repeating unit cell)! We will discuss these in Chapter Two Penrose tiling in 2D

The 2D Bravais lattices Note that this is the proper primitive cell for the centered rectangular lattice type (why? It contains only one lattice point) (this is called a rhombus)

The 3D Bravais Lattices! In 3D, there are 7 lattice systems, which give rise to 14 bravais lattices! The general lattice is triclinic, and all others are derived from putting restraints on the triclinic lattice! Know the conditions of each lattice (excellent test question )

The 14 Bravais lattices in 3D! Notice that we know have different lattice types:! P = primitive (1 lattice point)! I = Body-centred (2 lattice pts)! F = Face- centred (4 lattice pts)! C = Side-Centred (2 lattice pts)! In this course, we will concentrate upon only a few of these types

Cubic lattices: SC, BCC and FCC! For cubic systems, we have three bravais lattices: the simple cubic (SC), bodycentred cubic (BCC) and facecentred cubic (FCC).! The simple cubic has 1 lattice point per unit cell, with a total area of a 3! Number of nearest neighbours: 6! Nearest neighbour distance: a! Number of next-nearest neighbours: 12! Next-nearest neighbour distance: 2a (prove this!) Packing fraction = (atomic volume)/ (bravais unit cell volume) Simple cubic lattice (4/3)π(a/2) 3 (a 3 ) = π / 6

The Body-Centred Cubic Lattice (Li (at room temp.), Na, K, V, Cr, Fe, Rb, Nb, Mo, Cs, Ba, Eu, Ta) Body- Centred Cubic Lattice (BCC) Packing fraction = (atomic volume)/ ( bravais unit cell volume) (4/3)π( 3a/4) 3 (a 3 /2) = 3π / 8! The body-centred cubic lattice has 2 lattice points per unit cell, with a total primitive cell volume of a 3 /2! Number of nearest neighbours: 8! Nearest neighbour distance: 3 a/2 = 0.866 a (prove this!)! Number of next-nearest neighbours: 6 (where are these?)! Next-nearest neighbour distance: a (prove this!)

The Body-Centred Cubic Lattice! The primitive cell of the BCC lattice is defined by the translation vectors: z a 1 = ½ a (x + y - z) a 2 = ½ a (-x+y + z) a 3 = ½ a (x - y + z) where x, y, and z are the Cartesian unit vectors. These translation vectors connect the lattice pt at the origin to the points at the body centres (and make a rhombohedron) The angle between adjacent edges is 109.3 a a 3 x a 1 a 2 See figure 11 in Kittel for a picture of the primitive cell in more detail y

The Face-Centred Cubic Lattice (Al, Cu, Ni, Sr, Rh, Pd, Ag, Ce, Tb, Ir, Pt, Au, Pb, Th)! The face-centred cubic lattice has 4 lattice points per unit cell, with a total primitive cell volume of a 3 /4! Number of nearest neighbours: 12! Nearest neighbour distance: a/ 2 = 0.707 a (prove this!)! Number of next-nearest neighbours: 6 (where are these?)! Next-nearest neighbour distance: a (prove this!) Packing fraction = (atomic volume)/ (bravais unit cell volume) = 2π / 6 (do this on your own)

The Face-Centred Cubic Lattice! The primitive cell of the FCC lattice is defined by the translation vectors: a 1 = ½ a (x + y) a 2 = ½ a (y + z) a 3 = ½ a (z + x) where x, y, and z are the Cartesian unit vectors. These translation vectors connect the lattice pt at the origin to the points at the face centres. The angles between the axes are 60

Wigner-Seitz cells for BCC, FCC lattices! Note: You can also construct Wigner-Seitz cells for the FCC and BCC lattices. These look a bit strange, but they will be useful when we look at reciprocal space in the next chapter.! These are made by taking the lines to the nearest and nextnearest neighbour points, and bisecting them with planes. The resulting figure is the Wigner-Seitz cell (which have the same volumes as the primitive cells we made above)

Wigner-Seitz cells BCC lattice Simple cubic lattice

Hexagonal unit cell! The primitive cell in a hexagonal system is a right prism based on a rhombus with an included angle of 120! Note here that a 1 = a 2 = a 3! Later, we will look at the hexagonal close-packed structure, which is this structure with a basis (and is related to the fcc structure). a 3 a 2 a 1 120 (primitive cell is in bold)

2024 © businessdocbox.com Privacy Policy | Terms of Service | Feedback