`S_1`: Bond angle of `H_2O` is `104.5^@`.
`S_2`: In `H_2O` the lone pair- lone pair repulsion overcomes the bond pair- bond pair repulsion

Given below are two statements : one is labelled as Assertion A and the other is labelled as Reason R: Assertion A: The H-O-H bond angle in water molecule is 104.5^(@) Reason R: The lone pair - lone pair repulsion of electrons is higher than the bond pair - bond pair repulsion. In the light of the above statements, choose the correct answer from the options given below:

Assertion : All F - S - F angle in SF_(4) are greater than 90^(@) but less than 180^(@) . Reason :The lone pair -bond pair repulsion is weaker than bond pair -bond pair repulsion

Hybridisation helps us to understand the geometry of the molecules. This is because hybridised orbitals are directed in space in some preferred directions to have stable arrangement, which determine the geometry. The common hybridisation are sp (linear), sp^(2) (trigonal planar), sp^(3) (tetrahedral), sp^(3)d (trigona bipyramidal), sp^(3)d^(2) (octahedral) and sp^(3)d^(3) (pentagonal bipyramidal). The presence of lone pairs in addition to bond pairs distort the geometry because "lone pair "-" lone pair repulsion"gt" lone pair "-" bond repulsion" gt" bond pair" -"bond pair repulsion" . What is the hybridisation and shape of XeF_(4) molecule?

Hybridisation helps us to understand the geometry of the molecules. This is because hybridised orbitals are directed in space in some preferred directions to have stable arrangement, which determine the geometry. The common hybridisation are sp (linear), sp^(2) (trigonal planar), sp^(3) (tetrahedral), sp^(3)d (trigona bipyramidal), sp^(3)d^(2) (octahedral) and sp^(3)d^(3) (pentagonal bipyramidal). The presence of lone pairs in addition to bond pairs distort the geometry because "lone pair "-" lone pair repulsion"gt" lone pair "-" bond repulsion" gt" bond pair" -"bond pair repulsion" . Give an example of molecule involving sp^(3) hybridisation.

Hybridisation helps us to understand the geometry of the molecules. This is because hybridised orbitals are directed in space in some preferred directions to have stable arrangement, which determine the geometry. The common hybridisation are sp (linear), sp^(2) (trigonal planar), sp^(3) (tetrahedral), sp^(3)d (trigona bipyramidal), sp^(3)d^(2) (octahedral) and sp^(3)d^(3) (pentagonal bipyramidal). The presence of lone pairs in addition to bond pairs distort the geometry because "lone pair "-" lone pair repulsion"gt" lone pair "-" bond repulsion" gt" bond pair" -"bond pair repulsion" . Do CH_(4), NH_(3) and H_(2)O involve same hybridisation of the central atom?

Hybridisation helps us to understand the geometry of the molecules. This is because hybridised orbitals are directed in space in some preferred directions to have stable arrangement, which determine the geometry. The common hybridisation are sp (linear), sp^(2) (trigonal planar), sp^(3) (tetrahedral), sp^(3)d (trigona bipyramidal), sp^(3)d^(2) (octahedral) and sp^(3)d^(3) (pentagonal bipyramidal). The presence of lone pairs in addition to bond pairs distort the geometry because "lone pair "-" lone pair repulsion"gt" lone pair "-" bond repulsion" gt" bond pair" -"bond pair repulsion" . Give an example of a molecule involving sp^(3)d hybridisation of the central atom and two lone pairs.

Hybridisation helps us to understand the geometry of the molecules. This is because hybridised orbitals are directed in space in some preferred directions to have stable arrangement, which determine the geometry. The common hybridisation are sp (linear), sp^(2) (trigonal planar), sp^(3) (tetrahedral), sp^(3)d (trigona bipyramidal), sp^(3)d^(2) (octahedral) and sp^(3)d^(3) (pentagonal bipyramidal). The presence of lone pairs in addition to bond pairs distort the geometry because "lone pair "-" lone pair repulsion"gt" lone pair "-" bond repulsion" gt" bond pair" -"bond pair repulsion" . Which d - orbitals are involved in sp^(3)d^(2) hybridisation in SF_(6) molecule?

Lone pair and pi -bonds exist in