Electronegativity & Bonding of the Period 3 Elements (Cambridge (CIE) AS Chemistry)
Revision Note
Trends in Period 3 Electronegativity & Bonding
Electronegativity
Electronegativity is the power of an element to draw the electrons towards itself in a covalent bond
Going across the period, the electronegativity of the elements increases
Electronegativity across Period 3 table
Period 3 element | Na | Mg | Al | Si | P | S | Cl | Ar |
|---|---|---|---|---|---|---|---|---|
Electronegativity | 0.9 | 1.2 | 1.5 | 1.8 | 2.1 | 2.5 | 3.0 | - |
Graph of the electronegativity of the Period 3 elements
Electronegativity of the Period 3 elements increases from Na to Cl
As the atomic number increases going across the period, there is an increase in nuclear charge
Across the period, there is an increase in the number of valence electrons however the shielding is still the same as each extra electron enters the same shell
As a result of this, electrons will be more strongly attracted to the nucleus causing an increase in electronegativity across the period
Bonding & structure of Period 3 elements table
Period 3 element | Na | Mg | Al | Si | P | S | Cl | Ar |
|---|---|---|---|---|---|---|---|---|
Bonding | Metallic | Metallic | Metallic | Covalent | Covalent | Covalent | Covalent | - |
Structure | Giant metallic | Giant metallic | Giant metallic | Giant molecular | Simple molecular | Simple molecular | Simple molecular | Simple molecular |
The table shows that going from Al to S the bonding changes from metallic to covalent and the structure changes from giant to simple structure
Na, Mg and Al are metallic elements which form positive ions arranged in a giant lattice in which the ions are held together by a ‘sea’ of delocalised electrons around them
Since Al donates three electrons into the sea of delocalised electrons to form an ion with +3 charge, the electrostatic forces between the electrons and the aluminium ion will be very strong
The electrons in the ‘sea’ of delocalised electrons are those from the valence shell of the atoms
Na will donate one electron into the ‘sea’ of delocalised electrons, Mg will donate two and Al three electrons
As a result of this, the metallic bonding in Al is stronger than in Na
This is because the electrostatic forces between a 3+ ion and the larger number of negatively charged delocalised electrons are much larger compared to a 1+ ion and the smaller number of delocalised electrons in Na
Since there are more electrons in a metallic lattice of aluminium compared to sodium and magnesium, aluminium is a better electrical conductor
A giant metallic lattice
Metal cations form a giant lattice held together by electrons that can freely move around
Si is a non-metallic element and has a giant molecular structure in which each Si atom is held to its neighbouring Si atoms by strong covalent bonds
There are no delocalised electrons in the structure of Si which is why silicon cannot conduct electricity and is classified as a metalloid
The giant molecular structure of silicon
The diagram shows the giant molecular structure of silicon where silicon atoms are held together by strong covalent bonds
Phosphorous, sulfur, chlorine and argon are non-metallic elements
Phosphorous, sulfur and chlorine exist as simple molecules (P4 , S8 , Cl2)
Argon exists as single atoms
The covalent bonds within the molecules are strong, however, between the molecules there are only weak instantaneous dipole-induced dipole forces
It doesn’t take much energy to break these intermolecular forces
The lack of delocalised electrons means that these compounds cannot conduct electricity
The simple molecular structure of phosphorous
The diagram shows the simple molecular structure of phosphorus with covalent bonds between the atoms
The simple molecular structure of sulfur
The diagram shows the simple molecular structure of sulfur with covalent bonds between the atoms
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