Functional Groups

Functional Groups if added to hydrocarbons change their functionality and properties. A hydrocarbon is a compound made up of hydrogen and carbon, which can be either saturated or unsaturated. A saturated hydrocarbon is one in which the carbon atoms are joined by only a single bond and an unsaturated hydrocarbon is one in which a double or triple bond between carbon atoms is present. Generally, a saturated hydrocarbon is very less reactive, but when another ‘atom’ or ‘group of atoms’ is attached to it, the resulting molecule becomes highly reactive depending on the attached group. The other ‘atom’ or ‘group of atoms in a carbon compound is called a functional group. 

What are Functional Groups?

A functional group is an atom or a group of atoms that makes a carbon compound or an organic compound reactive and determines its properties. 

Functional groups are atoms within molecules that have distinct properties regardless of the other atoms in the molecule. In organic chemistry, functional groups are the substituent atoms or groups of atoms that are connected to certain molecules. The halo group, alcohol group, aldehyde group, ketone group, carboxylic acid group, alkene group, alkyne group, etc. are some of the most important functional groups in organic chemistry.

List of Functional Groups

All the useful functional groups can be listed as follows:

• Hydrocarbons
• Halo (Alkyl Halide) Group
• Alcohol Group
• Aldehyde Group
• Ketone Group
• Carboxylic Acid Group

Hydrocarbons

• Alkene Group is a carbon-carbon double bond. The compounds containing the alkene group are known as alkenes. The homologous series of alkenes have the general formula C_nH_2n, where n is the number of carbon atoms in one molecule.
• Alkyne Group is a carbon-carbon triple bond. The compounds containing the alkyne group are known as alkynes. The homologous series of alkynes have the general formula C_nH_2n-2, where n is the number of carbon atoms in one molecule.

Learn about, Alkanes, Alkenes, and Alkynes

Halo (Alkyl Halide) Group

Depending on whether a chlorine, bromine, or iodine atom is attached to a carbon atom of the organic compound, the halo group can be chloro (-Cl), bromo (-Br), or iodo (-I). Since the elements chlorine, bromine, and iodine are collectively known as halogen, the Chloro, Bromo, and Iodo groups are referred to as halo groups and are denoted by the symbol -X.

Haloalkanes are formed when one hydrogen atom in an alkane is replaced with a halogen atom. Haloalkanes have the general formula C_nH_2n+1X, where X represents the halogens. R-X is the formula for haloalkanes, where R is an alkyl group and X is the halogen atom. 

Alcohol Group 

One oxygen and one hydrogen atom are joined together to form the alcohol group (-OH) and they are also known as the hydroxyl group. Any class of organic compounds that include one or more hydroxyl (OH) groups linked to a carbon atom of the alkyl group is an alcoholic group. 

Alcohols are organic water (H₂O) derivatives in which one of the hydrogen atoms has been replaced by an alkyl group, which is often represented by R in organic structures. 

Ethanol [C₂H₅OH] and methanol [CH₃OH] are the most common examples of alcohol. The homologous series of alcohols have the general formula C_nH_2n+1OH. Alcohols are employed as sweeteners and in the manufacture of perfumes, as well as being important intermediates in the synthesis of other compounds. 

Aldehyde Group

One carbon atom, one hydrogen atom, and one oxygen atom are joined together to form the aldehyde group (-CHO). Any organic compound in which a carbon atom has a double bond with an oxygen atom, a single bond with a hydrogen atom, and a single bond with another atom or group of atoms (designated R in general chemical formulas and structure diagrams) is called an aldehyde.

Aldehydes have the general molecular formula C_nH_2nO, where n is the number of carbon atoms in one molecule. Many aldehydes have pleasant scents, and they are created by dehydrogenation (removal of hydrogen) from alcohols, which is how the term “aldehyde” was derived. The two simple aldehydes are formaldehyde HCHO also known as methanal and acetaldehyde CH₃CHO also known as ethanal.

Ketone Group

One carbon atom and one oxygen atom make up the ketone group (-CO-). The presence of a carbonyl group, in which the carbon atom is covalently bonded to an oxygen atom, distinguishes ketone from other organic molecules. Other than oxygen carbon is attached to the alkyl groups or hydrocarbon radicals (R) form the remaining two bonds. 

Since a ketone group is always found in the middle of a carbon chain, a ketone must have at least three carbon atoms in its molecules, one ketone group carbon atom, and two carbon atoms on both sides. Ketones with less than three carbon atoms are not really possible. Ketone has the general molecular formula C_nH_2nO where n is the number of carbon atoms in one molecule. The simplest ketone is acetone CH₃COCH₃, also known as propanone. 

The physiological effects of ketone molecules are significant. They can be present in a variety of sugars as well as pharmaceutical chemicals such as natural and synthetic steroid hormones. The anti-inflammatory drug cortisone contains three ketone groups in its molecules.

Carboxylic Acid Group

Carboxylic acids, often known as organic acids, are organic molecules that include the carboxylic acid group. Carboxylic acids are sometimes known as alkanoic acids.

The carbonyl (C=O) and hydroxyl (-OH) groups together make up the carboxyl (-COOH) group, where carbon from carbonyl group is attachd to hydroxyl group with single bond. 

The homologous series of carboxylic acids have the general formula R-COOH, where R represents an alkyl group. Acetic acid CH₃COOH also known as ethanoic acid is the most common carboxylic acid.

The image added below shows the nomenclature of the various functional groups.

Ether group

The Ether group is similar to alcohols but instead of hydrogen, there is an alkyl group attached to oxygen. The oxygen molecule (-O-) is attached to two alkyl groups (R and R’) with a single bond, forming the ether group. R-O-R’ is the general formula for the ether group. Ethers are very useful and diverse compounds as they are used in the formation of resins, dyes, plastic, paints, oils, etc.

Functional Group Table

The table of most of the useful functional groups is as follows:

Functional Group and Formula	Suffix	Example
Halo Alkanes, R-X	Alkyl Halide	Ethyl Chloride
Alcohol, R-OH	-ol	Butanol, Propanol
Aldehyde, R-CHO	-al	Methnal (Formeldehyde)
Carboxylate, R-COO–	-oate	Sodium Ethanoate (Sodium Acetate)
Carboxylic Acid, R-COOH	-oic acid	Ethanoic Acid (Acetic Acid)
Ester, R-(CO)-O-R’	Alkyl Alkanoate	Ethyl Butanoate (Ethyl Butyrate)
Acyl Halide, R-(CO)-X	-oyl halide	Ethanoyl Chloride (Acetyl chloride)
Ether, R-O-R’	Alkyl Ether	Diethyl Ether (Ethoxyethane)

Nomenclature of Common Functional Groups

The nomenclature is the systematic way of naming organic molecules with a set of rules established by the IUPAC (International Union of Pure and Applied Chemistry). The basic rules of this system are as follows:

• Firstly, identify the longest chain in the organic compound.
• Number the chain of carbon from the side which contains a higher-priority functional group.
• Name the chain with the prefix meth, eth, prop, but, pent, etc with respect to the number of carbon present in the longest chain.
• Name the functional group of the compounds using the appropriate suffixes according to the present functional group.
• If there is more than one functional group present in the chain, the highest priority functional group decides the suffix, and other functional groups are used as a prefix, with alphabetic order (if there is still more than one functional group left after deciding the suffix)

Example: Name the organic compound, CH₃CH₂CHClCOOH.

Solution:

Number the carbon atoms in the given compound, from -COOH side as it is the most reactive group in the given compound. i.e.,

 

As, there are 4 carbon in the longst present chain. It’s name starts with bute, and there is chlorine at second carbon.

Thus, its name is 2-chloro buten-1-oic acid.

Example: What is the IUPAC name of the organic compound CHClBrCH₂CHO?

Solution: 

Number the carbon atoms in the given compound, from -CHO side as it is the most reactive group in the given compound. i.e.,

 

As there are 3 carbon present in the longest chain, it’s name starts with prop root word and there are bromine and cholrine attached to the third carbon.

Thus, name of the given compounds is 3-bromo-3-cholor propen-1-al

Learn more about, Nomenclature of Alcohols, Phenols, and Ethers

Sample Questions on Functional Groups

Question 1: Write the molecular formula for the alcohol group with 4 carbon atoms.

Answer:

The molecular formula for the alcohol group is C_nH_2n+1OH. If there are 4 carbon atoms then n=4, this means C₄H₂₍₄₎₊₁OH or C₄H₉OH. So the required molecular formula is C₄H₉OH

Question 2: Can the compound C₂H₄O be a ketone group?

Answer:

A ketone must have at least three carbon atoms in its molecules, one ketone group carbon atom, and two carbon atoms on both sides. Ketones with less than three carbon atoms are not really possible. In the given compound, we have 2 carbon atoms, so it is not a ketone group.

Question 3: What is the molecular formula of aldehyde which is derived from butane?

Answer:

Aldehydes have the general molecular formula C_nH_2nO, where n is the number of carbon atoms in one molecule. Since butane C₄H₁₀ has 4 carbon atoms, so n=4, this means C₄H₂₍₄₎O or C₄H₈O. Hence the molecular formula of aldehyde which is derived from butane is C₄H₈O.

Question 4: Identify the functional group present in the compound C₃H₈O.

Answer:

In the given compound C₃H₈O, the number of carbon atoms is 3, so n=3. First check if it satisfies the molecular formula of alcohol, aldehyde, ketone, or carboxylic acids. Since it has only one oxygen atom, so it cannot be a carboxylic group. Alcohol has the general molecular formula C_nH_2n+1OH, where n is the number of carbon atoms in one molecule. Put n=3 in this formula, we get C₃H₂₍₃₎₊₁OH or C₃H₇OH or C₃H₈O which matches the given compound. So the given compound have alcohol as its functional group.

Question 5: Write the molecular formula for the alkene group and alkyne groups containing 5 carbon atoms.

Answer:

Given that there are 5 carbon atoms, so n=5. Alkenes have the general formula C_nH_2n, where n is the number of carbon atoms in one molecule. Put n=5 in this formula, C₅H₂₍₅₎ or C₅H₁₀.

Alkynes have the general formula C_nH_2n-2, where n is the number of carbon atoms in one molecule. Put n=5 in this formula, so C₅H₈ or C₅H₈.

Hence the molecular formula for the alkene group is C₅H₁₀ and the alkyne group is C₅H₈.

Read More,

• Classification of Organic Compounds
• Haloalkanes and Haloarenes

FAQs on Functional Groups

Q1: What are Functional Groups?

Answer:

A functional group is an atom or a group of atoms that makes a carbon compound or an organic compound reactive and determines its properties. For example, alcohal, aldehyde, ketones, ether, carboxylic acid, etc.

Q2: How many Functional Groups are present in Acetic Acid?

Answer:

As the molecular formula for acetic acid is CH₃COOH, the only functional group present is carboxylic acid (-COOH).

Q3: What are the main Functional Groups present in Carbohydrates?

Answer:

Carbohydrates are either polyhydroxy aldehydes or polyhydroxy ketones; thus, functional groups present in carbohydrates are,

• Alcohals
• Aldehydyes
• Ketones

Q4: What is a Carboxy Group?

Answer:

By combining carbonyl (-CO-) and hydroxyl (-OH), we get the carboxyl group (-COOH). It is also known as carboxylic acid and is one of the most useful groups in organic chemistry.