1. Metals: Model of Bonding Link to Bozeman Science

2. STAGES OF TECHNOLOGY IN HUMAN CIVILIZATION

3. Stone Age

4. Bronze Age

5. Middle Ages

6. Modern Times

8. Introduction – Properties of Metals/ Importance in Civilization List at least 5 Properties of Metals List at least 5 Properties of Metals What do the terms “Stone Age” / “Bronze Age” and “Iron Age” mean in the context of civilizations? Why are metals so important in human history? What do the terms “Stone Age” / “Bronze Age” and “Iron Age” mean in the context of civilizations? Why are metals so important in human history? Copper age video

9. Properties of Metals Luster (Shine) Luster (Shine) Malleable Malleable Ductile Ductile Excellent Conductor of Heat and Electricity Excellent Conductor of Heat and Electricity Can form Alloys Can form Alloys

10. Models of Bonding Between Atoms Covalent – electrons shared locally between 2 nuclei Covalent – electrons shared locally between 2 nuclei Ionic – electron(s) transferred from metal to nonmetal to form ions Ionic – electron(s) transferred from metal to nonmetal to form ions

11. Metallic Bonding – “Sea of Electrons Model” In Metal crystal – electrons are mobile and delocalized (constantly moving throughout entire metal crystal). In Metal crystal – electrons are mobile and delocalized (constantly moving throughout entire metal crystal). The valence electrons in metals do not belong to any particular nucleus, but rather are shared by all the different nuclei.

12. Bonding in metals can be visualized as positively charged cations (nucleus & core electrons) surrounded by a “sea” of delocalized valence electrons Note: Gray sphere = cations: Red spheres = delocalized valence electrons Link to metallic bonding video clip

13. Properties of Metals LUSTER 1) LUSTER (polished surfaces reflect light). Most metals appear silvery white (“metallic shine”) because they reflect essentially all wavelengths of light.

14. Explanation of Luster Explanation: Electrons constantly moving in different positions near many different nuclei experience a hugh range of energies and hence can make nearly every possible quantum energy transition possible which releases light in the visible range of light.

15. Properties of Metals 2) Malleable – can be shaped; (often requires melting, then resetting shape and allowing to cool). 3) Ductile – can be drawn into a wire Examples: 1 gram of gold can drawn into a wire over 1 mile long. Examples: 1 gram of gold can drawn into a wire over 1 mile long.

16. IONIC AND COVALENT BONDS BREAK WHEN RELATIVE POSITIONS OF ATOMS ARE SHIFTED IONIC COMPOUNDS COVALENT COMPOUNDS Ions shift positions, + ions next to + ions, - ions next to - ions Ions shift positions, + ions next to + ions, - ions next to - ions Bonding electrons must stay directly between bonding nuclei Bonding electrons must stay directly between bonding nuclei

17. Properties of Metals Ductile (easily drawn into a wire) Ductile (easily drawn into a wire) Malleable (easily deformed, bent, hammered into thin sheets). Since electrons in a metal crystal are delocalized, metal electrons can shift their positions to still be attracted to different nuclei within the crystal when the nuclei shift positions..

18. Metals are EXCELLENT Conductors of Heat

19. 4) CONDUCTION EXPLANATION: EXPLANATION: MOBILE, DELOCALIZED, ELECTRONS rapidly carry the kinetic energy to different atoms throughout the metal crystal HEAT

20. 5) Metals are EXCELLENT Conductors of Electricity Explanation: Electrical Current = Flow of Charge. Mobile (moving) Electrons carry current in metals. Electrons enter metal crystal at negative electrode and exit at the positive electrode. animation electrical conductivity

21. Electrical Conduction Moving e - carries charge; Electric current = flow of charge # of e - entering # of e- exiting ( from – electrode) (from + electrode) = -ELECTRODE-ELECTRODE +ELECTRODE+ELECTRODE

22. Alloys – stronger bonding due to addition of carbon or different metal Substitute different metal to increase strength Add carbon to iron to increase strength of steel. Less carbon = more flexible steel Making Stuff Stronger Steel Steel