Lecture 2.1 Crystalline Solids.

Slides:

Advertisements

Similar presentations

INTRODUCTION TO CERAMIC MINERALS

Advertisements

Fundamental Concepts Crystalline: Repeating/periodic array of atoms; each atom bonds to nearest neighbor atoms. Crystalline structure: Results in a lattice.

Nanochemistry NAN 601 Dr. Marinella Sandros

Lecture 2.1 Crystalline Solids. Poly-crystalline solids - Grains Mono-crystalline solids- Whiskers, Wafers.

CHAPTER 2 : CRYSTAL DIFFRACTION AND PG Govt College for Girls

When dealing with crsytalline materials, it is often necessary to specify a particular point within a unit cell, a particular direction or a particular.

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.

Announcements 1)Revised Lab timings: 1-3 PM (all groups) 2) Quiz 1, 28 th Jan 2014, Tuesday 7:30 PM, WS 209, WS 213.

Lec. (4,5) Miller Indices Z X Y (100).

Solid Crystallography

Miller indices and crystal directions

Solid State Physics 2. X-ray Diffraction 4/15/2017.

Recall Engineering properties are a direct result of the structure of that material. Microstructure: –size, shape and arrangement of multiple crystals.

X-Ray Diffraction ME 215 Exp#1. X-Ray Diffraction X-rays is a form of electromagnetic radiation having a range of wavelength from nm (0.01x10 -9.

Miller Indices And X-ray diffraction

Remember Miller Indices?

Discussion Notes Farzana Ansari Feb 14 & 16, 2012.

Solid State Physics (1) Phys3710

Lecture 3.0 Structural Defects Mechanical Properties of Solids.

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

Crystal Structure A “unit cell” is a subdivision of the lattice that has all the geometric characteristics of the total crystal. The simplest choice of.

MSE 630 Introduction to Solid State Physics Topics: Structure of Crystals classification of lattices reciprocal lattices bonding.

W.D. Callister, Materials science and engineering an introduction, 5 th Edition, Chapter 3 MM409: Advanced engineering materials Crystallography.

Crystallographic Points, Directions, and Planes. ISSUES TO ADDRESS... How to define points, directions, planes, as well as linear, planar, and volume densities.

Chapter 3: Structures via Diffraction Goals – Define basic ideas of diffraction (using x-ray, electrons, or neutrons, which, although they are particles,

ENGR-45_Lec-04_Crystallography.ppt 1 Bruce Mayer, PE Engineering-45: Materials of Engineering Bruce Mayer, PE Licensed Electrical.

Linear and Planar Atomic Densities

STRUCTURE OF SOLID MATERIALS CLASSIFICATION OF SOLIDS SOLIDS CLASSIFIED AS CRYSTALLINE, AMORPHOUS OR A COMBINATION OF THE TWO. CRYSTALLINE - BUILT UP OF.

Last lecture Introduction to materials science and engineering Atoms / electron configuration.

Chapter 6 Solid-State Chemistry. Problems n n 6.9, 6.13, 6.14.

Properties of engineering materials

ENGINEERING PHYSICS.

Engg Physics Crystal Structure

ME 330 Engineering Materials

Crystallography : How do you do? From Diffraction to structure…. Normally one would use a microscope to view very small objects. If we use a light microscope.

Crystal Structure NaCl Well defined surfaces

CHARACTERIZATION OF THE STRUCTURE OF SOLIDS

Ch.4 Atomic Structure of Solid Surfaces.

Crystal Structure and Crystallography of Materials

Properties of engineering materials

Remember Miller Indices?

Crystallographic Points, Directions, and Planes.

THE SPACE LATTICE AND UNIT CELLS CRYSTAL SYSTEMS AND BRAVAIS LATTICES.

CHAPTER 3: STRUCTURE OF CRYSTALLINE SOLIDS

Groups: Fill in this Table for Cubic Structures

Concepts of Crystal Geometry

Dislocations and Strengthening

Structure and manufacturing Properties of Metals

CRYSTAL STRUCTURE & X-RAY DIFFRACTION

Semiconductor Processing Single Crystal Silicon

Crystal Structure Continued!

Lecture 2.1 Crystalline Solids.

Crystallographic Points, Directions, and Planes.

X-Ray Diffraction and Reciprocal Lattice

X-ray Neutron Electron

Chapter 1 Crystallography

Chapter 3: Structures via Diffraction

UNIT-1 CRYSTAL PHYSICS.

Structural Defects Mechanical Properties of Solids

Structural Defects Mechanical Properties of Solids

Crystal and X-ray Diffraction

MSE420/514: Session 1 Crystallography & Crystal Structure

Electron diffraction Øystein Prytz.

MILLER PLANES Atoms form periodically arranged planes Any set of planes is characterized by: (1) their orientation in the crystal (hkl) – Miller indices.

Crystal physics.

MODULE 2 - Introduction to Basic Crystallography

CRYSTAL IMPERFECTIONS

Chapter 3: Crystal & Amorphous structure in materials Part 1

Crystalline Solids (고체의 결정구조)

Chapter 16: Electron Diffraction

Presentation transcript:

Lecture 2.1 Crystalline Solids

Crystalline Solids Poly-crystalline solids - Grains Mono-crystalline solids- Whiskers, Wafers

Crystal Lattices

Crystal Systems =>14 Bravais Lattices

Bravais lattice (abc) Lattice is constructed of repeated unit cells Lattice Point - 1/3a,1/2b,1/4c Crystallographic Direction (vector from 0,0,0 to xyz) which is defined by [uvw] smallest set of integers having the same ratio as xyz bar over number = minus number

Close Packed Structures Cubic, BCC, FCC, HCC are the focus of this course Determining distances and volume fractions in Cubic Structures

Miller indices for a plane (hkl) Family of Miller Planes {hkl}

EXAMPLE- Miller Index intercepts on a,b&c axes=3,1&2, respectively reciprocals = 1/3,1/1&1/2, respectively smallest set of integers with same common ratio = 2,6&3 Miller indexes of Plane, (hkl)=(263) also called “reciprocal space plane”

Family of Planes {110}

Measuring Structure with X-rays Generate X-ray radiation X-ray Diffraction (=90) ao= cubic lattice parameter

X-Ray Generation Electron Scattering Electron Kickout K,K, L, L Broad Band X-rays Electron Kickout K,L,M shell electron Replace with higher electron Transition gives X-rays one wave length K,K, L, L K K

X-ray Generation Energy Level Diagrams 4 -1.51 eV 3 L L K L -3.40 eV 2 K K -13.6 eV 1

X-ray Camera-1 Single Crystal Camera Broad Band X-rays all  in source only Bragg (diffracting) wavelengths reflect

SiGe Crystal

X-ray Camera-2 (film strip) X-rays of Single  All (hkl) planes are exposed at all angles at all times Diffraction of Bragg planes

Electron Diffraction Electrons of different energy Focused Electrons Electrons of different energy Transmission through sample CCD detector Thinned Sample CCD Detector

Seeing Crystal Structure with and Atomic Force Microscope Electron Microscope Atomic Force Microscope Scanning Tunneling Microscope

Diffracting Planes

Changing Crystal Structure – Allotropic Phase Change HCP->FCC->BCC->SC Ca(fcc) --(447ºC)-> Ca(bcc) Co(hcp) --(427ºC)--> Co(fcc) Fe(bcc) --(912ºC)-->Fe(fcc) --(1394ºC)-->Fe(hcp) Na(bcc) --(-233ºC)--> Na(hcp) Ti(hcp) --(883ºC)-->Ti(bcc) Zr(hcp) --(872ºC)--> Zr(bcc) Decreasing density with increasing temperature!

Defects in Crystal Structure Vacancy, Interstitial, Impurity Schottky Defect Frenkel Defect Dislocations – edge dislocation, line, screw Grain Boundary

Effect of Structure on Mechanical Properties Elasticity Plastic Deformation