Introduction :
Diagram of VSEPR theory Chart
The
two scientists R.S Nyholmm and R.J Gillespie proposed the VSPER theory
in 1957. VSEPR theory helps us in explaining the repulsion caused
between the atoms, bonds and lone electron pairs in a molecule. VSEPR
theory was developed to predict the shapes of the molecule in which
atoms are bonded, including the repulsion facts.
VSEPR Theory Definition:
Valence Shell Electron Pair Repulsion (VSEPR) theory is a phenomenon used in chemistry to predict the shapes of the individual molecules based on the repulsion acting between the electrons pairs in a molecule. The other name if VSPER theory is Gillespie-Nyholm theory, named after its two main developers. In this theory, it is explained that, valance electron pairs surrounding an atom mutually repel each other and hence they will arrange themselves in such a geometry, which minimizes their repulsion between electron pairs. The number of electron pairs around an atom, that is bonding and non-bonding are called steric number. The number of electron pairs in the valance shell of a central atom is concluded by drawing the Lewis structure of the molecule in which all lone electron pairs will be shown with bonds.Diagram of VSEPR theory Chart
Postulates of VSEPR Theory:
The main postulates of VSEPR theory are:- The total number of electron pairs (bonding and non-bonding) determines the shape of the molecule and on the orientation of the electron pairs around the central atom.
- To minimize the repulsion between the atoms, the electron pairs arrange themselves fare away from the central atom.
- The electron pairs around the central atom can be shared electron pairs or lone pairs. The shared electron pairs are known as Bond pairs.
- The strength of repulsions between different electron pairs is in the order:
Lone pair - Lone pair > Lone pair - Shared pair > Shared pair - Shared pair.
Prediction of shapes using VSEPR theory
VSEPR theory could predict the shapes of a molecules correctly . The following examples prove this :
a) BeCl2 has two single Be-Cl bonds and these two bond pairs of electrons on Be atom are oriented farthest in the opposite directions to have minimum repulsions between them . BeCl2 is a linear molecule . Similarly CO2 molecule has two carbon - oxygen double bonds . These bond pairs of electrons are oriented in opposite directions to have minimum repulsion . Hence , CO2 is called linear molecule O = C = O .
b) In BCl3 there are three B-Cl single bonds or there are three bonded electron pairs around 'B' in the valence shell and they are oriented farthest apart to have minimum repulsion among them . Hence BCl3 molecule has trigonal planar structure with `|__ClBCl` bond angle 120o .
c) All the four electron pairs in methane (CH4) are bond pairs only. Therefore , the molecule is tetrahedral with a bond angle of 109o29' .
d) Nitrogen in NH3 has four electron pairs .
e) In water molecule, the central atom , oxygen has two lone pairs and two bond pairs of electrons . The number of lone pairs on oxygen is grater than those on nitrogen in ammonia . Due to stronger lone pair - lone lone pair repulsions , the bond angle decreases to 104o30'. Thus , the water molecule is 'V' shaped and not linear.
a) BeCl2 has two single Be-Cl bonds and these two bond pairs of electrons on Be atom are oriented farthest in the opposite directions to have minimum repulsions between them . BeCl2 is a linear molecule . Similarly CO2 molecule has two carbon - oxygen double bonds . These bond pairs of electrons are oriented in opposite directions to have minimum repulsion . Hence , CO2 is called linear molecule O = C = O .
b) In BCl3 there are three B-Cl single bonds or there are three bonded electron pairs around 'B' in the valence shell and they are oriented farthest apart to have minimum repulsion among them . Hence BCl3 molecule has trigonal planar structure with `|__ClBCl` bond angle 120o .
c) All the four electron pairs in methane (CH4) are bond pairs only. Therefore , the molecule is tetrahedral with a bond angle of 109o29' .
d) Nitrogen in NH3 has four electron pairs .
e) In water molecule, the central atom , oxygen has two lone pairs and two bond pairs of electrons . The number of lone pairs on oxygen is grater than those on nitrogen in ammonia . Due to stronger lone pair - lone lone pair repulsions , the bond angle decreases to 104o30'. Thus , the water molecule is 'V' shaped and not linear.
