Group 3 Presentation Chemistry PDF

Summary

This presentation covers the chemical concepts of carboxylic acids, esters, and their derivatives. It includes discussions of nomenclature, properties, and applications of these compounds. The presentation is likely a teaching resource.

Full Transcript

GROUP 3
PRESENTATION
CHEMISTRY
 WHAT IS CARBOXYLIC ACID?

Carboxylic acids are a type of organic compound
that contains a special group of atoms called a
carboxyl group. This group consists of a carbon
atom (C) double-bonded to an oxygen atom (O) and
single-bonded to another oxygen atom (O) that is
also bonded to a hydrogen atom (H).
STRUCTURE

- The carboxyl group is the defining feature of
carboxylic acids. It is represented as -COOH.
O
- The carboxyl group is attached to a carbon chain,
which can be straight, branched, or cyclic. ||
- The carbon atom in the carboxyl group is bonded — C — OH
to a hydrogen atom.
NOMENCLATURE
O
1. FIND THE LONGEST CHAIN
EX:
||
O CH₃-CH₂-CH₂-C-OH
||
CH₃-CH₂-CH₂-C-OH Butanoic acid
2. COUNT THE CARBONS
EX: OTHER NAMES OF CARBOXYLIC ACIDS:
4 Carbons = But—
Methanoic acid
3. ADD "ANOIC ACID" Ethanoic acid
EX: Propanoic acid
But— + anoic acid Pentanoic acid
PHYSICAL PROPERTIES CHEMICAL PROPERTIES

SMELL : have a sour smell ACIDITY : carboxylic acids are
sour and acidic
MELTING AND BOILING POINT :
higher melting and boiling REACTION WITH BASES : the
point compared to other mixture becomes less acidic
organic compounds
REACTION WITH ALCOHOL :
SOLUBILITY : small carboxylic they can create a new
acids mix well with water molecule called esters
APPLICATIONS OF CARBOXYLIC ACIDS
Plastics
Paints
Textiles
Parmaceuticals
Detergents
Cosmetics
Preservation of foods
 WHAT IS ESTERS?
Esters are a class of organic
compounds that result from the
reaction between a carboxylic acid
and an alcohol.
general formula RCOOR
 ESTERIFICATION
Esterification is a process or a general name
for a chemical reaction, in which two reactants
(alcohol and an acid) form an ester as the
reaction product. Interestingly, esters can also
be split back to alcohols and carboxylic acids by
the action of water, dilute acid or dilute alkali.
This process is known as ester hydrolysis.
(Byju's 2023)
 NOMENCLATURE
1. Identify the alcohol and acid parts of
the ester.
2. Name the alcohol part first: Replace
the "-anol" ending of the alcohol with
"-yl."
3. Name the acid part next: Replace the
"-ic acid" ending of the acid with "-
oate.
NOMENCLATURE
EXAMPLE: CH₃COOCH₃
The alcohol part is methanol (CH₃OH), which becomes
"methyl."
The acid part is acetic acid (CH₃COOH), which becomes
"acetate."
The ester name is methyl acetate.
CHEMICAL PROPERTIES PHYSICAL PROPERTIES
Smell: Fruity and pleasant.
Hydrolysis: Produces acids State: Small esters are usually
and alcohols. liquids; larger ones can be
solids.
Transesterification: Forms Boiling Point: Lower than alcohols
new esters and alcohols. and acids of similar size.
Solubility: Soluble in water if small;
Reduction: Converts to less soluble as they get larger.
Density: Generally less dense than
primary alcohols.
water.
Color: Colorless in pure form.
Ammonia/Amines Reaction:
Produces amides
 USES OF ESTERS
Fragrances and Flavors: In perfumes and
foods.
Solvents: For paints and adhesives.
Plasticizers:
Enhance plastic flexibility.
Pharmaceuticals: In drug production.
Biodiesel: Renewable fuel.
DERIVATIVES OF ESTERS
LACTONES
LACTAMS
THIOESTERS
PHOSPHORIC ESTERS

These derivatives play significant roles in
various chemical reactions, biological
processes, and industrial applications,
highlighting their importance in both
nature and technology.
 LACTONES
Lactones are cyclic esters derived from
organic acids. They result from the
reaction between a hydroxyl group and
a carboxylic acid group within the same
molecule of hydroxycarbonic acid.
What are lactones used for?
How does lactones form?

1. Flavor & Aroma
2. Food Additives A lactose forms by bringing
3. Medicinal Uses together specific groups in
4. Industrial Uses a molecule, removing
water, and closing the
structure into a ring.
LACTAMS
Lactams are cyclic amides formed when a
carboxylic acid group and an amine group
in the same molecule react to create a loop.
This structure makes them stable and
important in various applications.

Examples: Caprolactam, Penicillin,
Cephalosporins
Purposes of lactams
How does lactams form?

1. Antibiotics
2. Medicinal Compounds A lactam forms by bringing
3. Chemical Reactions together specific groups in
a molecule, removing
water, and closing the
structure into a ring.
 THIOESTERS
Thioesters are organic compounds similar
to regular esters, but they contain a sulfur
atom instead of an oxygen atom in the ester
linkage. They are formed when a carboxylic
acid reacts with a thiol.

Examples: Acetyl-CoA, Succinyl- CoA,
Benzoyl-CoA
Purposes of thioesters
How does thioesters form?

1. Energy Storage So, a thioester forms by
2. Biochemical Reactions bringing together a
3. Synthesis of Molecules carboxylic acid and a thiol,
removing water, and
bonding the remaining
parts.
PHOSPHORIC ESTERS
are organic compounds that form when phosphoric
acid (H₃PO₄) reacts with an alcohol. In this process, the
hydroxyl groups of the phosphoric acid are replaced
by alkyl or aryl groups, resulting in a phosphate ester
bond.

Example: ATP, Nucleotides, Phospholipids
 Functions
Formation

1. Energy Storage & phosphoric esters are
Transfer made by mixing
2. Cell Membrane phosphoric acid with an
Structure alcohol, removing water,
3. Biochemical Reactions and forming a new
compound.
DERIVATIVES OF CARBONXYLIC ACIDS

chlorides Carboxylic acid derivatives are compounds
anhydride that can be converted back to carboxylic
estern acids by hydrolysis. These include acid
amides chlorides, acid anhydrides, esters, and
amides.
They share a common feature: the carbonyl
group (C=O) attached to different atoms or
groups replacing the hydroxyl group (-OH) of
the carboxylic acid.
 Acid [Acly]Chlorides

Acid chlorides, also known as acyl Structure: A carbonyl
chlorides, are a class of organic group (C=O) attached to
a chlorine atom (-Cl).
compounds derived from
carboxylic acids by replacing the
hydroxyl group (-OH) of the R Properties: Highly
reactive and commonly
carboxyl group (-COOH) with a used to make esters and
chlorine atom (-Cl). Their general amides.
Example:
formula is RCOCl, where R ethanoyl chloride-
represents an alkyl or aryl group. CH3COCl, propanoyl Reactions: React with
chloride- C2H5COCl, water to form carboxylic
butanoyl chloride-
acids and HCl.
C3H7COCl, benzoyl
chloride
 Acid Anhydride
Structure: Two acyl groups
(R-CO) joined by an oxygen
Acid anhydrides are organic atom.
compounds formed by the
removal of water (H₂O) from
Properties: Less reactive
two carboxylic acid molecules.
than acid chlorides, but still
They have the general formula
react with water, alcohols,
R–CO–O–CO–R', where R and R'
can be the same or different
hydrocarbon groups. Acid
R R and amines.

anhydrides contain two Reactions: React with water
carbonyl (C=O) groups to form two carboxylic acid
connected by an oxygen atom molecules.
ACID ACID
CHLORIDE ANHYDRIDES
O O
II II
CH3 C CH3 C Ethanoic
/

/
| | ANHYDRIDES
CI O
|
Ethan OLY CHLORIDE CH3 C

/
O

II
 acid chlorides
property acid anhydrides
[acyl chlorides]

General Formula R-COCI R-CO-O-CO-R

Highly reactive, especially with Less reactive than acid
Reactivity
water chlorides

Formed from dehydration of
Formed from carboxylic acids +
Formation carboxylic acids or from
halogenatin g agents
carboxylate salts

Used in organic synthesis (esters, Used in esterification, amidation,
Applications
amides, ketones) and aspirin production

Highly corrosive, reacts violenty less corrosive but still reactive
Handling
with water with water
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 AMINES DEFINITION
Amines are like little building blocks that
are found in many important things, like
proteins and medicines. They're made
up of a nitrogen atom (N) that's attached
to one, two, or three other groups of
atoms. These groups can be simple
chains of carbon and hydrogen, or they
can be more complex rings of atoms.
 TYPES OF AMINES
H
Primary Amines: Have one group attached to |
N - CH3
the nitrogen atom. |
H

CH3
|
Secondary Amines: Have two groups attached H - N - CH3
to the nitrogen atom. |
H

Tertiary Amines: Have three groups attached to CH3
|
the nitrogen atom CH3 - N - CH3
|
CH3
 Properties of Amines
Amines have some interesting features:

Solubility: Some Basicity: Amines
Smell: Many amines can dissolve in are like little
amines have a water, especially the magnets that can
strong smell, smaller ones. This is attract hydrogen
sometimes because the nitrogen ions (H+). This
described as fishy atom in amines can makes them basic,
or ammonia-like. attract water meaning they can
molecules. neutralize acids.
 Reactions of Amines
Amines are very reactive and can Acylation: Amines can react with acids to
participate in many different chemical form amides, which are important for
reactions. Here are a few examples: making plastics and other materials.

Alkylation: Amines can react with other Reaction with Nitrous Acid: Amines react
chemicals to add new groups of atoms with nitrous acid in a way that depends
to the nitrogen atom. This is like building on how many groups are attached to
onto a structure. the nitrogen atom. This reaction is used
to identify different types of amines.
 Applications of Amines
Amines are used in many different ways:

- Medicines: Amines are found in many medicines, like painkillers and
antidepressants.

- Plastics: Amines are used to make plastics, like nylon and polyurethane.

- Dyes: Amines are used to make dyes that color our clothes and other things.

- Agriculture: Amines are used to make pesticides and herbicides that help
protect crops.
 WHAT ARE AMIDES?

Amides are a group of organic
compounds formed when a carboxylic
acid reacts with an amine or ammonia.
Amides are made through a reaction
called amidation.
 NOMENCLATURE
1. Identify the amine and acid parts of the amide.

2. Name the acid parts first: Replace the "- ic acid" or
"-oic acid of the carboxylic acid with "amide"
⁸
3. If there is a group attached to the nitrogen atom ( N ),
name them as prefixes with "N- before the name.

Example: CH3CONH2

The acid part is acetic acid (CH3COOH)
which becomes "acetamide.
The name is acetamide
 PROPERTIES OF AMIDES
STRUCTURE: AND AMIDES HAVE A NITROGEN ATOM ATTACHED TO A
CARBONYL GROUP (C=O), WHICH GIVES THEM UNIQUE PROPERTIES.

SMELL: UNLIKE AMINES, MOST AMIDES DON'T HAVE A STRONG SMELL. THEY
ARE USUALLY ODORLESS.

SOLUBILITY: SMALL AMIDES CAN DISSOLVE IN WATER BECAUSE OF THE
NITROGEN AND OXYGEN ATOMS THAT CAN FORM BONDS WITH WATER
MOLECULES.

STABILITY: AMIDES ARE MORE STABLE COMPARED TO OTHER SIMILAR
COMPOUNDS LIKE ESTERS, MEANING THEY DON'T REACT EASILY
 REACTIONS OF AMIDES

Amides can participate in several reactions, but
they are less reactive than other nitrogen-containing
compounds.

Here are a few examples: 

Hydrolysis: Amides can break down into carboxylic acids and
amines when treated with water and an acid or base.

Reduction: Amides can be turned into amines by removing the
oxygen atom when treated with reducing agents.

Dehydration: Amides can lose water to form nitriles, another type
of nitrogen-containing compound.
TYPES OF AMIDES

Amides can be grouped into three types:
Primary, Secondary, and Tertiary.
The difference between them is how many
groups are attached to the nitrogen ( N ) atom.
APPLICATIONS OF AMIDES

Medicine: Amides are found in many medicines and drugs.

Plastics: Amides are used to make strong materials like nylon.

Proteins: Amide bonds, called peptide bonds, are what hold
proteins together in our bodies.

Industry: Amides are used in making fertilizers and dyes for
different products.
THANK YOU!