sp2
The central oxygen atom in H3O+ has sp3 hybridization. This means that the oxygen atom in H3O+ forms four equivalent bonds with the three hydrogen atoms and the lone pair, resulting in a tetrahedral geometry.
In H2O, the central atom is Oxygen atom and it is sp3 hybridised
sp3d bond angle(s): 180
sp3 , 2 lone pairs, 1 single bond to the oxygen, 1 double bond to oxygen
The central atom in ClO3 is Cl (chlorine). It forms three sigma bonds with the oxygen atoms, leading to a trigonal planar molecular geometry. The hybridization of the central Cl atom is sp2.
The central oxygen atom in H3O+ has sp3 hybridization. This means that the oxygen atom in H3O+ forms four equivalent bonds with the three hydrogen atoms and the lone pair, resulting in a tetrahedral geometry.
In H2O, the central atom is Oxygen atom and it is sp3 hybridised
The hybridization of MnO4- is sp3. Each oxygen atom contributes one electron to form single bonds with manganese, leading to the sp3 hybridization of the central manganese atom.
sp3d bond angle(s): 180
There can be a number of different heteroatoms depending on which alcohol it is. The heteroatom that would be common between all alcohols is oxygen.
sp3 , 2 lone pairs, 1 single bond to the oxygen, 1 double bond to oxygen
The central atom in ClO3 is Cl (chlorine). It forms three sigma bonds with the oxygen atoms, leading to a trigonal planar molecular geometry. The hybridization of the central Cl atom is sp2.
The central oxygen in CO is sp hybridized. The carbon atom donates one of its p orbitals to form a sigma bond with the oxygen atom. This results in the formation of two sp hybrid orbitals on the oxygen atom.
The nitrogen atom in NOBr has sp2 hybridization, as it forms three sigma bonds with oxygen and bromine atoms. This hybridization allows for the formation of a trigonal planar molecular geometry in NOBr.
The boron atom in BF3 has sp2 hybridization.
The carbon atom in CF4 has a hybridization of sp3.
The hybridization of the central atom in NCl3 is sp3.