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WHAT IS ORGANIC CHEMISTRY?

Let us start with the question "What is Organic chemistry?".

The simple answer is: It is the chemistry of carbon containing compounds, which are otherwise known as

organic compounds.

So it is pretty easy to recognize that we should start our journey of organic chemistry  by exploring the chemical

nature of carbon.

WHAT IS CARBON?

So the next question is: What is carbon? 

* Carbon is an element with atomic number (Z) = 6.

* Its ground state electronic configuration can be represented as: 1s22s22p2 (or) 1s22s22px12py12pz0 

* It is the first element in Group-14 of Long form of  Periodic table. 

* It is a non metal.

* On Pauling's scale, its electronegativity value is around 2.5.

* It usually forms covalent bonds.

* Its valency is 4 since there are four electrons in the outer shell i.e., it can form four covalent bonds with other

atoms.

WHY THERE ARE MILLIONS OF ORGANIC COMPOUNDS?

It is well known that there are millions of organic compounds  around, which are either originated from the

nature or prepared synthetically.Examples of organic compounds include carbohydrates, proteins, enzymes, vitamins, lipids, nucleic acids ,

synthetic polymers, synthetic fabrics, synthetic rubbers, plastics, medicines, drugs, organic dyes and so on.

Now the immediate question is: Why the carbon atom is so special and forms millions of compounds? 

To answer this question, we should know about catenation.

Catenation  is the ability of atoms of same element to bond covalently among themselves and form long chains

or rings. 

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Carbon has a stronger tendency to catenate since it is a smaller atom and can form stronger covalent bonds with

other carbons. The C-C bonds are stronger due to effective overlapping of atomic orbitals.

It also forms stronger bonds with other elements like hydrogen, oxygen, nitrogen, halogens, sulfur, phosphorus

etc.

The organic compounds can also exhibit isomerism due to different structural and spatial arrangement of atoms

or groups leading to formation of huge array of compounds.

These arguments explain why the carbon can form millions of compounds and organic chemistry is flourishing

like nothing.

HOW DOES CARBON FORM CHEMICAL BONDS?

LEWI'S DOT MODEL

Carbon is an appreciably electronegative element and tends to form four covalent bonds by using all the four

electrons in its valence shell i.e., the second shell for which the electronic configuration can be written as 2s22p2.

Hence the combining power or the valency of carbon is 4. It can form 4 bonds with other atoms.

It is possible to understand the bonding in carbon compounds by using Lewi's dot model.  According to this

model, each atom participating in the bonding contributes one electron to form an electron pair which is shared

between the two contributing atoms. Thus a covalent bond is formed. If atoms share two electron pairs, a double

bond is formed. And a triple bond is formed when three electron pairs are shared.

The purpose of participating in bond formation is to get the nearest inert gas configuration and thus by getting

stability. Most of the atoms try to get eight electrons or octet configuration in the valence shell. This is also called as

octet rule.

The structures of some simple organic molecules are explained as shown below.

Methane, CH4: The carbon atom contributes four valence electrons to make four bonds with hydrogen atoms.

Each hydrogen also contributes one electron for the bond formation.

Thus there are 4 C-H bonds in the methane molecule and carbon gets octet configuration in the valence shell.

Note that the valency of hydrogen atom is one. It can form only one bond since there is only one electron in this

atom. It also gets Helium's configuration during bond formation.

 Also note that in Lewi dot models, only the valence electrons are shown. The bond pairs can also be shown bylines. 

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Ethane, C2H6: In Ethane molecule each carbon forms 4 bonds again. Among them three are C-H bonds, while

the fourth one is a C-C bond.

Ethylene, C2H4: In this molecule, there is a double bond between two carbon atoms due to sharing of two pairs

of electrons. Each carbon also forms two bonds with hydrogen atoms.

Acetylene, C2H2: There is a triple bond between two carbon atoms in acetylene molecule. It is formed due to

sharing of three electron pairs. Each carbon also forms a single bond with hydrogen atom.

Methyl fluoride, CH3F: Since there are 7 electrons in the valence shell of Fluorine, it require one electron to

complete octet. Hence it contributes one electron for bond formation with carbon as shown below.

Note that the only the bond pairs are shown as lines in the second representation.

There are three lone pairs and one bond pair around fluorine atom. The bond pair is shown as a line.

In the same way, carbon atom forms bonds with other halogen atoms.

Formaldehyde, CH2O: There are six electrons in the valence shell of oxygen. It forms two bonds by contributing

two of its valence electrons and thus by completing the octet. In formaldehyde, the oxygen atom forms two bonds

with a carbon atom.

Methyl alcohol, CH3OH: However, the oxygen atom can also form just one bond with the carbon as in case of

methyl alcohol. It forms the second bond with hydrogen.

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Hydrogen cyanide, HCN: The carbon atom can also form bonds with nitrogen. In hydrogen cyanide there is a

triple bond between carbon and nitrogen. The nitrogen atom contributes three of its valence electrons for the

formation of this triple bond.

Methyl amine, CH3NH2: In this molecule, the carbon and nitrogen atoms are sharing only one pair of electrons.

However this model could not explain the exact geometry of organic molecules. For example, methane molecule

is tetrahedral, whereas ethylene is a planar molecule. These structures with exact bond angles cannot be explained

by this model. Therefore it is necessary to understand the structures of these molecules by using valence bond

theory as explained in the next section.

VALENCE BOND THEORY

 According to valence bond theory, four unpaired electrons are required to form four covalent bonds. But there

are only 2 unpaired electrons in the valence shell of carbon in the ground state.

However it is possible to get 4 unpaired electrons by transferring one of the electrons from 2s orbital into the

empty 2p orbital. This process is called excitation and carbon is said to be in the excited state. Now the electronic

configuration of carbon in the excited state becomes 2s12p3.

 A small amount of energy, which is available during the chemical bond formation, is sufficient for a carbon atom

to undergo excitation.

It is now possible for carbon atom to form 4 bonds in the excited state.

However, carbon undergoes hybridization before forming actual chemical bonds with other atoms.

Hybridization is the process of intermixing of two or more pure atomic orbitals of almost same energy to form

same number of identical and degenerate new orbitals known as hybrid orbitals. 

The carbon atom can undergo three types of hybridizations i.e., sp3 or sp2  or sp.

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SP3 HYBRIDIZATION OF CARBON

In sp3 hybridization, one 2s and three 2p orbitals of excited carbon intermix together and form 4 hybrid orbitals

which are oriented in tetrahedral geometry in space around the carbon atom. Each sp 3 hybrid orbital is occupied by

one electron.

Each of these sp3 orbitals can form σ-bond with other atom. Thus carbon is forming four single bonds with other

atoms in tetrahedral geometry. The bond angles are usually equal to or nearer to 109o28'.

E.g. In methane molecule, CH4, the carbon atom undergoes sp3 hybridization and forms four σ-bonds with

hydrogen atoms.

Note that whenever carbon atom undergoes sp3 hybridization, it forms 4 σ-bonds i.e., 4 single bonds.

SP2 HYBRIDIZATION OF CARBON

In sp2 hybridization, there is intermixing of one 2s and two of the 2p orbitals of carbon in the excited state to form

three hybrid orbitals. These are oriented in trigonal planar geometry. Each sp 2  hybrid orbital is occupied by one

electron. The remaining pure 2p orbital with one electron lies at right angle to the plane of hybrid orbitals.

The sp2 hybrid orbital form 3 σ-bonds in trigonal planar geometry. Thus the bond angles are about 120o. The

remaining pure 'p' orbital will form a π-bond. Thus carbon f orms total four bonds i.e., three σ-bonds and one π-bond.

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E.g. In ethylene molecule, C2H4, each carbon atom undergoes sp2 hybridization. Each carbon forms 2 σ-bonds

with hydrogens and one σ-bond with another carbon. The remaining pure 'p' orbitals on two carbons overlap sidewise

to form a π-bond. Thus there is a double bond between two carbons.

Note that whenever carbon atom undergoes sp2 hybridization, it forms 3 σ-bonds and 1 π-bond i.e., two single

bonds and one double bond.

SP HYBRIDIZATION OF CARBON

In sp hybridization, one 2s and one 2p orbitals of excited carbon intermix to form two sp-hybrid orbitals in linear

geometry. Each sp hybrid orbital is occupied by one electron. The remaining pure 2p orbitals ( for our convenience,

let us say: 2py and 2pz) orient at right angles to the sp-hybrid orbitals. These are also occupied by one electron each.

The two sp hybrid orbitals form 2 σ-bonds in linear geometry. Thus the bond angle will be about 180o. The

remaining pure 'p' orbitals will form two π-bonds. Thus carbon again forms total four bonds i.e., two σ-bonds and two

π-bonds.

E.g., In acetylene molecule, C2H2, each carbon undergoes sp hybridization and forms one σ-bond with a

hydrogen atom and one σ-bond with another carbon. The two carbon atoms also form two π-bonds with each other

due to sidewise overlapping of pure p-orbitals. Thus a triple bond is formed between two carbon atoms in acetylene

molecule.

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Note that whenever carbon atom undergoes sp hybridization, it forms 2 σ -bonds and 2 π-bonds. It may either

form one triple bond as in case of acetylene or two double bonds e.g. allenes.

The following diagram summarizes the bonding pattern by carbon atom in different hybridizations.

Hybridization  sp3 hybridized carbon  sp2 hybridized carbon  sp hybridized carbon 

Geometry 

Bond angle  109o28' 120o  180o 

Type of bonds 

4 single bonds

i.e., 4 σ bonds 

2 single & 1 double bonds

i.e., 3 σ bonds & 1 π-bond

1 triple & 1 single bondsor

2 double bonds

i.e., 2 σ bonds & 2 π-bonds