Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 23 Alloys Chemistry, The Central Science, 11th edition

Published byWerner Kramer Modified over 5 years ago

Similar presentations

Presentation on theme: "Chapter 23 Alloys Chemistry, The Central Science, 11th edition"— Presentation transcript:

1 Chapter 23 Alloys Chemistry, The Central Science, 11th edition
Theodore L. Brown; H. Eugene LeMay, Jr.; and Bruce E. Bursten Chapter 23 Alloys © 2009, Prentice-Hall, Inc.

2 Physical Properties of Metals
Conduct heat and electricity. Are malleable (can be pressed or hammered into sheets). Are ductile (can be drawn into wire). Are packed so atoms can slip past each other. So metals aren’t as brittle as other solids. © 2009, Prentice-Hall, Inc.

3 Electron-Sea Model Metals can be thought of as cations suspended in “sea” of valence electrons. Attractions hold electrons near cations, but not so tightly as to impede their flow. © 2009, Prentice-Hall, Inc.

4 Electron-Sea Model This explains many of the properties of metals, like Conductivity of heat and electricity; Deformation. © 2009, Prentice-Hall, Inc.

5 Alloys Alloys are mixtures of elements that have properties characteristic of metals. Many of the ordinary uses of metals involve alloys. © 2009, Prentice-Hall, Inc.

6 Substitutional Alloys
Components of alloys are dispersed uniformly— In substitutional alloys, solute particles take the place of solvent metal atoms. The particles in these alloys are quite close in size, of comparable radius. © 2009, Prentice-Hall, Inc.

7 Substitutional Alloys
Density of substitutional alloys typically lies between those of the component metals Alloy remains malleable and ductile. e.g. brass – Some Cu substitutes for Zn © 2009, Prentice-Hall, Inc.

8 Interstitial Alloys In interstitial alloys, solute particles find their way into the holes between solvent metal atoms. In this type of alloy the solute particles are smaller than the solvent particles. © 2009, Prentice-Hall, Inc.

9 Interstitial Alloys The interstitial atoms make the lattice more rigid, decreasing malleability and ductility. e.g. steel, where carbon is the interstitial atom © 2009, Prentice-Hall, Inc.

Download ppt "Chapter 23 Alloys Chemistry, The Central Science, 11th edition"

Similar presentations

Ionic Bonding.

Ionic Bonding.
Bonding in Metals OBJECTIVES:

Bonding in Metals OBJECTIVES:
Chapter 7 “Ionic and Metallic Bonding”

Chapter 7 “Ionic and Metallic Bonding”
Chapter 7 “Ionic and Metallic Bonding”. Metallic Bonds are… l How metal atoms are held together in the solid. l Metals hold on to their valence electrons.

Chapter 7 “Ionic and Metallic Bonding”. Metallic Bonds are… l How metal atoms are held together in the solid. l Metals hold on to their valence electrons.
Metals and Metallurgy © 2009, Prentice-Hall, Inc. Chapter 23 Metals and Metallurgy Chemistry, The Central Science, 11th edition Theodore L. Brown; H. Eugene.

Metals and Metallurgy © 2009, Prentice-Hall, Inc. Chapter 23 Metals and Metallurgy Chemistry, The Central Science, 11th edition Theodore L. Brown; H. Eugene.
I. Metallic Bonds  How atoms are held together in the solid form.  Metals hold onto their valence electrons very weakly.  Think of them as positive.

I. Metallic Bonds  How atoms are held together in the solid form.  Metals hold onto their valence electrons very weakly.  Think of them as positive.
7.4 Metallic Bonds and the Properties of Metals

7.4 Metallic Bonds and the Properties of Metals
Metallic Bonds and Properties of Metals. Metals Metals are made up of closely packed cations surrounded by electrons, rather than neutral atoms or ions.

Metallic Bonds and Properties of Metals. Metals Metals are made up of closely packed cations surrounded by electrons, rather than neutral atoms or ions.
Chapter 8 Metallic Bonding

Chapter 8 Metallic Bonding
Chemistry. Metallic Bonds  sea of electrons – metal atoms contribute their valence electrons  delocalized electrons – electrons are free to move throughout.

Chemistry. Metallic Bonds  sea of electrons – metal atoms contribute their valence electrons  delocalized electrons – electrons are free to move throughout.
Chapter 12 – Solids and Modern Materials 11

Chapter 12 – Solids and Modern Materials 11
Chapter 8 (p 228-231) Chemistry Mr. Gilbertson.

Chapter 8 (p ) Chemistry Mr. Gilbertson.
Chemistry Chapter 8 Notes 3. Review Compounds Can all be represented by chemical formulas Are connected by chemical bonds Ionic Metallic Covalent Compounds.

Chemistry Chapter 8 Notes 3. Review Compounds Can all be represented by chemical formulas Are connected by chemical bonds Ionic Metallic Covalent Compounds.
Chapter 15. Metallic Bonds Holds metals together by sharing the electrons (sea of electrons) VERY STRONG.

Chapter 15. Metallic Bonds Holds metals together by sharing the electrons (sea of electrons) VERY STRONG.
Chapter 7 “Metallic Bonding” Chemistry Grade 10. Bonding in Metals OBJECTIVES: –Explain the importance of alloys.

Chapter 7 “Metallic Bonding” Chemistry Grade 10. Bonding in Metals OBJECTIVES: –Explain the importance of alloys.
Section 4: Metallic Bonds and the Properties of Metals

Section 4: Metallic Bonds and the Properties of Metals
Metallic Bonds Quartz. Metal atoms are arranged in very compact and orderly patterns. Although metals do not bond ionically, they often form lattices.

Metallic Bonds Quartz. Metal atoms are arranged in very compact and orderly patterns. Although metals do not bond ionically, they often form lattices.
YouTube video 1:21. valence electrons detach from individual atoms since metals contain only 1-3 valence electrons and a low ionization energy bonding.

YouTube video 1:21. valence electrons detach from individual atoms since metals contain only 1-3 valence electrons and a low ionization energy bonding.
Chapter 5.4 Bonding in Metals. Standards: 8.7.c. Students know substances can be classified by their properties, including their melting temperature,

Chapter 5.4 Bonding in Metals. Standards: 8.7.c. Students know substances can be classified by their properties, including their melting temperature,
Metallic Bonding 7.3. Electron Sea Model The electron sea model proposes that all the metal atoms in a metallic solid contribute their valence electrons.

Metallic Bonding 7.3. Electron Sea Model The electron sea model proposes that all the metal atoms in a metallic solid contribute their valence electrons.

Similar presentations

Ads by Google