FAD1018 W14 — Polymer Chemistry

Week 14 lecture covering polymer chemistry. Source files: W14 (1).pdf, W14 (2).pdf from lecture notes folders; Lecture Slide Polymer - 2026 ppt_v1.2.pdf (inbox).

Summary

Introduction to polymers including classification, polymerization mechanisms, important synthetic and natural polymers. This lecture also covers proteins as natural polymers (amino acids, peptide bonds, protein structure).

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Part A: Proteins as Natural Polymers (W14-1)

Learning Outcomes

1. Identify the general structure of amino acids.
2. Identify the structures of the 20 standard amino acids.
3. Name amino acids according to IUPAC rules.
4. Define zwitterion and isoelectric point (pI).
5. Draw the structure of a given amino acid in acidic, basic, and at pI.
6. Explain the reactions of amino acids.
7. Describe the formation of a peptide bond in a polypeptide.
8. Explain the structure of proteins and the importance of amino acids and proteins.

1. Amino Acids

General Structure

All standard amino acids contain:

• An α-amino group (–NH₂)
• A carboxyl group (–COOH)
• A hydrogen atom
• A distinctive side chain (R group) attached to the α-carbon

N[C@@H](R)C(=O)O

Note: Glycine is the only achiral standard amino acid (R = H).

The 20 Standard Amino Acids

Amino Acid	3-Letter	1-Letter	R Group	SMILES (neutral)
Glycine	Gly	G	–H	NCC(=O)O
Alanine	Ala	A	–CH₃	CC(N)C(=O)O
Valine	Val	V	–CH(CH₃)₂	CC(C)C(N)C(=O)O
Leucine	Leu	L	–CH₂CH(CH₃)₂	CC(C)CC(N)C(=O)O
Isoleucine	Ile	I	–CH(CH₃)CH₂CH₃	CCC(C)C(N)C(=O)O
Methionine	Met	M	–CH₂CH₂SCH₃	CSCCC(N)C(=O)O
Phenylalanine	Phe	F	–CH₂–C₆H₅	NC(Cc1ccccc1)C(=O)O
Tryptophan	Trp	W	–CH₂–indole	NC(Cc1c[nH]c2ccccc12)C(=O)O
Proline	Pro	P	– (cyclic)	O=C(O)C1CCCN1
Serine	Ser	S	–CH₂OH	NC(CO)C(=O)O
Threonine	Thr	T	–CH(OH)CH₃	CC(O)C(N)C(=O)O
Cysteine	Cys	C	–CH₂SH	NC(CS)C(=O)O
Tyrosine	Tyr	Y	–CH₂–C₆H₄OH	NC(Cc1ccc(O)cc1)C(=O)O
Asparagine	Asn	N	–CH₂CONH₂	NC(=O)CC(N)C(=O)O
Glutamine	Gln	Q	–CH₂CH₂CONH₂	NC(=O)CCC(N)C(=O)O
Aspartic acid	Asp	D	–CH₂COOH	NC(CC(=O)O)C(=O)O
Glutamic acid	Glu	E	–CH₂CH₂COOH	NC(CCC(=O)O)C(=O)O
Lysine	Lys	K	–(CH₂)₄NH₂	NCCCC(N)C(=O)O
Arginine	Arg	R	–(CH₂)₃NHC(=NH)NH₂	NC(CCCNC(=N)N)C(=O)O
Histidine	His	H	–CH₂–imidazole	NC(Cc1c[nH]cn1)C(=O)O

Zwitterion and Isoelectric Point (pI)

In aqueous solution, amino acids exist predominantly as zwitterions — dipolar ions carrying both a positive and a negative charge.

[NH3+]CC(=O)[O-]

• Zwitterion: A molecule with equal positive and negative charges simultaneously.
• Isoelectric point (pI): The pH at which the amino acid has no net charge (exists mainly as the zwitterion).

pH Dependence of Charge

Medium	Carboxyl Group	Amino Group	Net Charge	Movement in Electrophoresis
Acidic (pH < pI)	–COOH (protonated)	–NH₃⁺ (protonated)	Positive (+1)	Moves toward negative electrode
pI	–COO⁻	–NH₃⁺	Neutral (0)	Does not move
Basic (pH > pI)	–COO⁻ (deprotonated)	–NH₂ (deprotonated)	Negative (–1)	Moves toward positive electrode

Key pKa values: α-COOH ≈ 2; α-NH₃⁺ ≈ 9–10.

Electrophoresis

At any pH other than the pI, amino acids migrate in an electric field:

• pH < pI → net positive charge → migrates to the cathode (–).
• pH > pI → net negative charge → migrates to the anode (+).

2. Peptides

Peptide Bond Formation

Amino acids are linked by peptide bonds (amide bonds) formed via a condensation reaction that eliminates water.

NCC(=O)O.NCC(=O)O>>NCC(=O)NCC(=O)O

Generic peptide bond between two amino acid residues:

N[C@@H](R1)C(=O)N[C@@H](R2)C(=O)O

• The bond forms between the α-carboxyl group of one amino acid and the α-amino group of the next.
• Not between the side chains (R groups).

Peptide Classification by Size

Class	Number of Amino Acid Residues
Dipeptide	2
Tripeptide	3
Oligopeptide	2 – 9
Polypeptide	10 – 100
Protein	> 40 (typically > 100)

N- and C-Termini

Every peptide chain has:

• A free N-terminal amino group (–NH₂ or –NH₃⁺) at one end.
• A free C-terminal carboxyl group (–COOH or –COO⁻) at the other end.

Nomenclature

Peptides are named from the N-terminus to the C-terminus.

• Full name: All residues except the C-terminal one use the -yl suffix.
• Three-letter abbreviation: e.g., Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg
• One-letter abbreviation: e.g., RPPGFSPFR

Examples

Ala-Gly-Ala (tripeptide):

CC(N)C(=O)NCC(=O)NC(C)C(=O)O

Ala-Cys (dipeptide):

CC(N)C(=O)NC(CS)C(=O)O

3. Proteins

Definition

• Proteins are polyamides containing 40 to several thousand amino acid residues.
• Each protein has a unique amino acid sequence that determines its shape and function.

Hydrolysis

Proteins can be hydrolyzed back to amino acids by:

• Boiling with dilute mineral acid (e.g., HCl)
• Boiling with aqueous alkali (e.g., NaOH)
• Enzymatic action (~40 °C)

Types of Proteins

Type	Description	Examples
Simple	Hydrolyze to amino acids only	Albumins, globulins
Fibrous	Long, stringy filaments; insoluble; structural support	Collagen, elastin, keratin
Globular	Folded spherical shape; enzymes, hormones, transport	Hemoglobin, myoglobin, lysozyme
Conjugated	Bonded to a non-protein group (prosthetic group)	Nucleoproteins, glycoproteins, mucoproteins

Levels of Protein Structure

Level	Description	Key Interactions	Examples
Primary	Linear sequence of amino acids; location of disulfide bridges	Peptide bonds (covalent)	Insulin
Secondary	Local folding into α-helices or β-pleated sheets	Hydrogen bonds between backbone C=O and N–H	Keratin (α-helix), silk fibroin (β-sheet)
Tertiary	Overall 3-D folding of a single polypeptide	Ionic bonds, H-bonds, disulfide bridges, van der Waals forces	Myoglobin, lysozyme
Quaternary	Association of two or more polypeptide subunits	Same as tertiary (inter-subunit)	Hemoglobin (4 subunits), collagen (triple helix)

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Part B: Synthetic and Natural Polymers (W14-2)

Learning Outcomes

1. Define and explain terminologies, condensation and addition polymerization
2. Classify polymers and describe their usage

Definitions

• Monomer: The large molecule from which a polymer is synthesized
• Polymer: The large molecule which is made up of many repeating units of monomers
• Repeating Unit: The basic structure of a polymer; by repetition it produces a long polymer chain

Example: Polyethene

C=C                          ; ethene (monomer)

Classification

By Number of Monomer Types

Homopolymer

Polymers made up from only one type of monomer.

F/C(F)=C(F)/F                ; tetrafluoroethylene (Teflon monomer)

Example — Teflon (PTFE):

• Monomer: Tetrafluoroethylene
• Polymer: Polytetrafluoroethylene (Teflon)

Copolymer

Polymers made up from two or more different monomers.

Type	Pattern	Description
Random	-A-B-B-A-B-A-A-B-	Repeating units in purely random fashion
Regular (alternating)	-A-B-A-B-A-B-A-B-	Regularly alternating units
Block	-A-A-A-A-B-B-B-B-	Occurs in blocks of different length
Graft	A-A-A-A-A… with B-B-B branches	Chain of one repeating unit grafted onto backbone of another

Example — Saran®:

• Monomers: 1,1-dichloroethene + 1-chloroethene
• Use: Film for wrapping food

By Structure

i) Linear Polymers

Linear or straight-chain polymer consisting of monomers linked in a straight and long continuous chain without any lateral linkage or branching.

ii) Branched Polymers

Polymers with branches at regular intervals along the polymer chain. These branches make it difficult for polymer molecules to pack in a regular array → less crystalline.

iii) Cross-linked Polymers

Formed when linear or branched polymer chains are joined together by covalent bonds through cross-linked process.

• Adding cross-links makes polymer more elastic
• When number of cross-links is relatively larger, polymer becomes more rigid

By Thermal Behavior

Type	Behavior	Structure
Thermoplastics	Flow when heated; can be molded into variety of shapes; retain shape when cool. Can be melted repeatedly.	Linear and branched polymers (no cross-linking). Weak forces between chains broken by heating.
Thermosets	Once cross-linked, shape cannot be changed without destroying plastic. Cannot be melted.	Heavy cross-linked polymers. Strong covalent bonds between chains.

Polymerization Mechanisms

I) Addition Polymerization

• Addition reaction in which unsaturated monomers (monomers with double bond) are joined together by covalent bonds to form a polymer without elimination of a small molecule
• Empirical formula of polymer is the same as empirical formula of monomer
• Polymers obtained are called addition polymers
• Peroxide (CH₃OOCH₃) is used as an initiator

Examples: Polyethylene, polyvinyl chloride, polystyrene, polyisoprene, teflon

Example 1: Polyethene (PE)

C=C                          ; ethene

Low-Density Polyethylene (LDPE) — Recycling code 4

• Discovered 1933 by ICI
• Conditions: 1200 atm, 200°C, O₂ — free radical mechanism
• Properties: Highly branched, cannot be packed closely together. Low mp (150°C), low density (0.92 g cm⁻³). Easily deformed and softens in boiling water.
• Uses: Plastic bags, wrapping sheet, bottles, electrical insulation

High-Density Polyethylene (HDPE) — Recycling code 2

• Manufactured 1953 by Karl Ziegler and Giulio Natta
• Conditions: 1 atm, 60°C, TiCl₄ + (C₂H₅)₃Al — Ziegler-Natta mechanism
• Properties: Mostly linear chains, closely packed, ordered structures. Density 0.96 g cm⁻³, mp 130–140°C. Stronger and harder.
• Uses: Molding rigid articles, agricultural/municipal/industrial pipes

Example 2: Polyvinyl chloride (PVC)

C=CCl                        ; chloroethene (vinyl chloride)

• Monomer: Chloroethene
• Uses: Pipes

Example 3: Polystyrene (PS)

c1ccccc1C=C                  ; phenylethene (styrene)

• Monomer: Phenylethene (styrene)
• Uses: Food packaging (foam containers)

Example 4: Polytetrafluoroethylene (PTFE, Teflon)

F/C(F)=C(F)/F                ; tetrafluoroethylene

• Monomer: Tetrafluoroethylene
• Uses: Non-stick coatings, thread seal tape

Example 5: Polypropylene (PP)

C=CC                         ; propene

• Monomer: Propene
• Due to methyl groups, polymeric chains can have different structures
• Presence of CH₃ increases intermolecular van der Waals forces but makes chain difficult to pack → lower density but higher melting point
• Uses: Ropes, moulds, bottles, kitchenware, carpets, battery containers

Example 6: Synthetic Rubber — Neoprene

C=C(Cl)C=C                   ; 2-chloro-1,3-butadiene (chloroprene)

• First synthetic rubber produced by polymerization of 2-chloro-1,3-butadiene
• Resistant to most chemicals
• Uses: Hoses for petrol, containers for corrosive liquids

Example 7: Styrene-butadiene rubber (SBR)

• Copolymer between styrene (phenylethene) and 1,3-butadiene in ratio 1:3
• Can be vulcanized like natural rubber
• Uses: Car tyres, footwares, carpetbacking

II) Condensation Polymerization

• Process that combines monomers with elimination of a small molecule such as water, methanol, hydrogen chloride, or ammonia
• Monomers must have at least two identical or different functional groups
• Polymers obtained are called condensation polymers

2 major classes:

1. Polyamide — formed when carboxylic acid with two -COOH reacts with amine with two -NH₂
2. Polyester — formed when carboxylic acid with two -COOH reacts with alcohol with two -OH

(A) Polyamides

Example 1: Nylon 6,6

NCCCCCCN                     ; hexane-1,6-diamine
O=C(O)CCCCC(=O)O             ; hexane-1,6-dioic acid (adipic acid)

• Monomers: Hexane-1,6-diamine + hexane-1,6-dioic acid
• By-product: nH₂O

Example 2: Nylon 6

NCCCCCC(=O)O                 ; 6-aminohexanoic acid

• Monomer: 6-aminohexanoic acid
• By-product: nH₂O

Example 3: Kevlar

Nc1ccc(N)cc1                 ; 1,4-diaminobenzene
O=C(O)c1ccc(C(=O)O)cc1       ; terephthalic acid

• Monomers: 1,4-diaminobenzene + terephthalic acid
• Properties: Very strong and flexible
• Uses: Bulletproof vests

(B) Polyester

• Repeating functional groups: ester
• Most familiar polyester: polyethylene terephthalate (PET), known as Dacron and Terylene

Example 1: Dacron (PET)

COC(=O)c1ccc(C(=O)OC)cc1     ; dimethyl terephthalate
OCCO                         ; 1,2-ethanediol (ethylene glycol)

• Monomers: Dimethyl terephthalate + ethylene glycol
• By-product: Methanol (nCH₃OH)
• Uses: Clothing, tyre cords, carpets

Example 2: Terylene

O=C(O)c1ccc(C(=O)O)cc1       ; benzene-1,4-dicarboxylic acid (terephthalic acid)
OCCO                         ; ethane-1,2-diol (ethylene glycol)

• Monomers: Terephthalic acid + ethane-1,2-diol
• By-product: Water (nH₂O)

Other Terminologies in Polymer Chemistry

Crystallites

• The large size of polymers means that they experience greater van der Waals forces than small molecules.
• Because these forces operate only at small distances, they are strongest if the polymer chains can line up in an ordered, closely packed array.
• The regions of the polymer in which the chains are highly ordered with respect to one another are called crystallites.
• The more crystalline (more ordered) the polymer is, the denser, harder, and more resistant to heat it is.

Elastomers

• An elastomer is a polymer that stretches and then reverts to its original shape.
• It is a randomly oriented amorphous polymer, but it must have some cross-linking so that the chains do not slip over one another.
• When elastomers are stretched, the random chains stretch out. The van der Waals forces are not strong enough to maintain them in that arrangement; therefore, when the stretching is removed, the chains go back to their random shapes.
• Rubber is an example of an elastomer.

Fibers

• Fibers are thin threads produced by passing a molten polymer through small holes in a die.
• When the fibers are cooled and drawn out, the crystalline regions orientate themselves along the axis of the fiber which adds considerable tensile strength.
• Examples of fibers are nylon, Dacron, and polyethylene.

Plasticizers

• A plasticizer is an organic compound that dissolves in the polymer, lowering the attractions between the polymer chains, which allows them to slide past one another.
• This makes the polymer more flexible.
• Example: Dibutyl phthalate (added to PVC to make flexible flooring).

Modification of Polymer Properties

Polymer properties can be deliberately modified by:

1. Changing the length of the polymer chain
2. Varying the chemical composition of the monomer units
3. Changing the branching of the polymer chains
4. Cross-linking the polymer chains
5. Varying the arrangement of the chains in the solid
6. Modifying the orientation of the monomer units within the chains

Polymer Research Fields

Fiber Reinforced Composites

• Used in building materials, vehicle parts, etc.
• Use of natural fiber vs synthetic fiber
• Waste to wealth, reduce manufacturing cost
• Sustainable, environmentally friendly

Drawbacks:

• Natural fiber has many hydrophilic –OH groups
• HDPE is entirely hydrophobic
• Weak adhesion between fiber and HDPE matrix
• Weak physical and mechanical properties
• Poor resistance to moisture

Research solutions:

• Use a compatibilizer to address the weaknesses (improves interface adhesion)

Sustainable Applications

• Sustainable GunPla made from eggshells (injection moulding)
• From crab shell to solar cell: gel polymer electrolyte based on N-phthaloylchitosan
• Self-healing coatings: UV-curable alkyd coatings for buildings and industrial structures
• Sustained drug delivery materials: nanofiber capsules that slowly release drugs into the body (less strain on kidney compared to immediate-release capsules)

Natural Polymers

Natural Rubber

• Polymer of 2-methyl-1,3-butadiene (isoprene)
• Isoprene undergoes addition polymerization to give poly(isoprene)
• Poly(isoprene) exists in two forms: cis and trans depending on relative spatial arrangement of the two -CH₂ groups

CC(=C)C=C                    ; isoprene (2-methyl-1,3-butadiene)

Vulcanization

• Natural rubber is soft, sticky, not strong or elastic
• To improve properties, it undergoes vulcanization process
• Soft rubber transformed to harder cross-linked polymer by heating rubber with sulphur atoms
• Long chains of polyisoprene are cross-linked by sulphur atoms
• Too much vulcanization makes rubber hard and brittle
• Vulcanized rubber uses: Tyres, footware, gloves, elastic bands, tubings, toys

Related Topics

• Amines & Amino Acids — Proteins as natural polymers
• Carboxylic Acids & Derivatives — Polyesters and polyamides
• Polymer Chemistry — General polymer concepts

Study Notes

[!note] Modern materials science Polymer chemistry connects organic chemistry to materials science. Know the major polymer types, their monomers, polymerization mechanisms, and applications.

[!tip] Exam focus Be able to draw monomers and repeating units for: PE, PVC, PS, PTFE, PP, nylon 6,6, nylon 6, Kevlar, Dacron, Terylene. Know conditions for LDPE vs HDPE synthesis. Understand cis/trans isoprene and vulcanization.

Related Course Page

• FAD1018 - Basic Chemistry II

References

• Nasrulzamani B. Mohd. Rodzi & Dr Ahmad Danial, Prof Madya Dr. Norbani Abdullah, Dr. Hazar Bebe Mohd Ismail. (2015). Comprehensive College Chemistry (Upgraded). SAP Publications.
• Wade, L. G. (2012). Organic Chemistry (8th Ed). Pearson Education.
• Brown, W. H., Iverson, B. L., Anslyn, E., & Foote, C. S. (2018). Organic Chemistry (8th Ed). Cengage Learning.
• Favre, H. A., & Powell, W. H. (2014). Nomenclature of Organic Chemistry: IUPAC Recommendations and Preferred Names 2013. Royal Society of Chemistry.
• Salleh, F. M., et al. (2014). Improvement in the mechanical performance of kenaf fiber reinforced high density polyethylene composites. Journal of Polymer Research, 21, 1-11.
• Yusuf, S. N. F., et al. (2016). From crab shell to solar cell: A gel polymer electrolyte based on N-phthaloylchitosan. RSC Advances, 6(33), 27714-27724.
• Saman, N. M., et al. (2019). UV-curable alkyd coating with self-healing ability. Journal of Coatings Technology and Research, 16, 465-476.
• Mazlan, M., et al. (2021). The impact of substitution of two hydrophobic moieties on the properties of guar gum based hydrogels. Pigment & Resin Technology, 50(6), 485-495.