Hybridisation in Organic Molecules (Cambridge (CIE) AS Chemistry)
Revision Note
Hybridised Atoms: Shapes & Bond Angles in Molecules
Each carbon atom has four electrons in its outer shell (electronic configuration: 1s22s22p2)
Carbon atoms share these four electrons in four covalent bonds with other atoms to achieve a full outer shell configuration
These electrons are found in orbitals within the respective atoms
When forming a covalent bond, the orbitals overlap in such a way to form two types of bonds
Sigma bonds (σ)
Pi bonds (π)
Hybridisation: sp3
The electron pair in a σ bond is found in a region of space between the nuclei of the two atoms that are sharing the electrons
The electrostatic attraction between the electrons (negatively charged) and the two nuclei (positively charged) holds the two atoms together
Carbon atoms that form four σ bonds are said to be sp3 hybridised
The four pairs of electrons around each carbon repel each other forcing the molecule to adopt a configuration in which the bonding pairs of electrons are as far away from each other as possible
The molecule adopts a tetrahedral arrangement with bond angles of 109.5 o
Bonding in ethane
The diagram shows a molecule of ethane in which each carbon atom forms four σ bonds to adopt a tetrahedral configuration and minimise the repulsion between the bonding pairs of electrons
Hybridisation: sp2
When carbon atoms use only three of their electron pairs to form a σ bond, they are said to be sp2 hybridised
Each carbon atom will have a p orbital with contains one spare electron
When the p orbitals of two carbon atoms overlap with each other, a π bond is formed (the π bond contains two electrons)
The two orbitals that form the π bond lie above and below the plane of the two carbon atoms to maximise bond overlap
The three bonding pairs of electrons are in the plane of the molecule and repel each other
The molecule adopts a planar arrangement with bond angles of 120 o
Bonding in ethene
The overlap of the two p orbitals results in the formation of a π bond in ethene (sp2 hybridised molecule) in which the bonding pair of electrons repel each other to force the molecule into a planar configuration with bond angles of 120o
Hybridisation: sp
Carbon atoms can also use only one of their electron pair to form a σ bond, in which case the carbon atoms are said to be sp hybridised
Each carbon atom will have two p orbitals with one spare electron each
When the four p orbitals of the carbon atoms overlap with each other, two π bonds are formed (each π bond contains two electrons)
The two orbitals that form the π bond lie above and below the plane of the carbon atoms
The two orbitals of the other π bond lie in front and behind the plane of the atoms
This maximises the overlap of the four p orbitals
The molecule adopts a linear arrangement with bond angles 180 o
Bonding in ethyne
The overlap of the p orbitals results in the formation of two π bonds in ethyne (sp hybridised molecule) which adopts a linear arrangement with bond angles of 180o
Examiner Tips and Tricks
A double bond is a combination of a σ and π bond and a triple bond is a combination of one σ and two π bonds
The strength of the bonds increases as follows: single < double < triple bond
This is due to the increased electron density around the C-C atom, making the bond stronger and more difficult to break.
Hybridised Atoms: σ and π Bonds in Molecules
σ bonds
Sigma bonds are formed from the end-on overlap of atomic orbitals
S orbitals overlap this way as well as p orbitals
Forming sigma bonds
Sigma bonds can be formed from the end-on overlap of s or p orbitals
The electron density in a σ bond is symmetrical about a line joining the nuclei of the atoms forming the bond
The pair of electrons is found between the nuclei of the two atoms
The electrostatic attraction between the electrons and nuclei bonds the atoms to each other
The arrangement of the σ bond in sp3, sp2 and sp hybridised carbon atoms
The σ orbitals are formed from the end-on overlap of the atomic orbitals resulting in symmetrical electron density on the atoms
π bonds
Pi (π) bonds are formed from the sideways overlap of p orbitals
The two lobes that make up the π bond lie above and below the plane of the atoms
This maximises the overlap of the p orbitals
Forming pi bonds
π bonds can be formed from the end-on overlap of p orbitals
In triple bonds, there is an additional overlap of p orbital
The two lobes of the π bond lie in front of and behind the plane of the atoms in the molecule
This maximises the overlap of the p orbitals
The arrangement of the π bond in sp3, sp2 and sp hybridised carbon atoms
The π bonds are formed from the sideway overlap of the atomic orbitals
Examiner Tips and Tricks
π bonds are drawn as two electron clouds, one arising from each lobe of the p orbitals
The two clouds of electrons in a π bond represent one bond consisting of two electrons (one from each orbital)
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