3.3 Metallic bonding Flashcards
What is metallic bonding?
A lattice of positively charged ions in a sea of delocalised e-
What does the number of delocalised e- depend on?
How many e- have been lost by each metal atom
How do metals have giant structures?
Metallic bonding spreads throughout
What is the name for the e- that are free to move about in a metal?
Delocalised e-
Why are metals good conductors of electricity?
- Have delocalised e- that can move throughout the structure and carry charge
Why are metals good conductors of heat?
- energy is spread by increasingly vigorous vibrations of the packed ions
What does the strength of the metal depend on?
- charge of the ion
- size of the ion
How does the charge of the ion affect the strength of metals?
- The greater the charge = the greater the no. of e-
- the stronger the electrostatic force of attraction between the +ve ions and the e-
How does the size of the ion affect the strength of the metals?
- the smaller the ion = the closer the e- to the +ve nucleus
- the stronger the bond
Describe the structure of solid magnesium and how its ions are held together
- the valence e- shell in each Mg atoms is delocalised
- makes +ve Mg2+
- attracted to delocalised e-
- the attraction holds the lattice together
Which out of a 2+ ion and a 3+ ion have a higher melting point?
3+ ion
- has a higher nuclear charge = more delocalised e-
- stronger electrostatic force of attraction
- more energy needed to be overcome
Why are metals malleable and ductile?
Malleable (beaten into shape)
Ductile (pulled into thin wires)
- after distortion, each metal ion is still in the same environment
- retains its new shape
Why do metals have a high melting point?
- have giant structures
- strong (electrostatic force of ) attraction between metal ions and delocalised e-
- need lots of energy to be overcome
