Polymer Science
Polymer Science is concerned with a group of chemical
substances composed of macromolecules. The field of polymer science includes in
multiple disciplines including chemistry, physics,
and engineering.
This science comprises
three main sub-disciplines:
- Polymer Chemistry, concerned with the chemical synthesis and chemical properties of polymers.
- Polymer Physics, concerned with the bulk properties of polymer materials and engineering applications.
- Polymer Characterization is concerned with the analysis of chemical structure and morphology and the determination of physical properties in relation to compositional and structural parameters.
What
are polymers?
Etymology of Polymer
The word polymer is derived from the Greek
words poly meaning "many" and meros
meaning "part".
The term was coined in 1833 by Jöns Jacob Berzelius.
What Makes Polymers Unique?
Really big molecules
(macromolecules) like polymers have
very different properties than small molecules
1. Chain
entanglement: Long polymer chains get
entangled with each other.
2. When the polymer is
melted, the chains can flow past each other.
3. Below the melting point, the chains
can move, but only slowly. Thus the plastic
is flexible, but cannot be easily stretched.
4. Below the glass
transition point, the chains become locked and the polymer is rigid
Reasons Why Polymers are Important
Plastics
can be formed by molding into intricate part shapes, usually with no further
processing required
Very
compatible with net shape processing
On a
volumetric basis, polymers:
Cost
competitive with metals
Generally
require less energy to produce than metals
Certain
plastics are translucent and/or transparent, which makes them competitive with
glass in some applications
General Properties of Polymers
1. Low density relative
to metals and ceramics
2. Good strength‑to‑weight
ratios for certain (but not all) polymers
3. High corrosion
resistance
4. Low electrical and
thermal conductivity
Limitations of Polymers as Engineering Materials
Low
strength relative to metals and ceramics
Low
modulus of elasticity (stiffness)
Service
temperatures are limited to only a few hundred degrees
Viscoelastic
properties, which can be a distinct limitation in load bearing applications
Some
polymers degrade when subjected to sunlight and other forms of radiation
Definition of Polymer
q
Definition
by Berzelius
Organic compounds which shared identical empirical
formulas but differed in overall molecular weight, the larger of the
compounds being described as "polymers" of the smallest.
Example:
Glucose (C6H12O6) would be a polymer of
Formaldehyde (CH2O)
q
Modern Definition
A Polymer is a large molecule (macromolecule) composed of a
long, repeating chain of smaller units called monomers.
- Polymers usually have high melting and boiling points.
- Subunits are connected together by covalent chemical bonds.
- Highest molecular weight among any molecules.
- There is virtually no upper end to the molecular weight range since giant three-dimensional networks may produce cross linked polymers of a molecular weight of many millions.
Macromolecule
q
Is a molecule composed of a great number of
atoms.
q
Has high relative molecular mass and molecular
weight.
q
Is a high reactive molecular mass, the structure
of which essentially comprises multiple repetition of uniting mass derived from
molecules of low reactive molecular mass.
Physical Properties
Substances, composed of macromolecules, often have unusual physical
properties
- Tendency to break easily. Example, DNA.
- Need for assistance in dissolving into solution (in the form of ions or salts, for example).
- High concentrations of macromolecules in a solution can alter the rates and equilibrium constants of the reactions of other macromolecules.
Example
- Organic macromolecules: bio-polymers (carbohydrates, proteins, lipids), synthetic polymers (plastics, synthetic fiber, rubber).
- Inorganic macromolecules: graphene, carbon nanotube.
Monomer
q
Is an atom or a
small molecule that may bind chemically to other monomers to
form a polymer.
Example
- natural: glucose, amino acid
- organic: ethylene, vinyl chloride, etc
Oligomer
Molecules with lower than 10 repeating units, the degree of
polymerization is between 2 to 10 i.e. n=2~10 exhibits quite different thermal
and mechanical properties compared to the corresponding high molecular weight
polymer.
Oligomeric styrene having 7 repeating units (n=7) is a viscous liquid
while commercial grade high molecular weight polystyrene is a brittle solid.
Some Common Polymers
Skeletal
Structure
·
Linear – a chain with two ends
Chemical Structure
·
Branched – have side chains
·
Crosslinked (Networked) – chains are connected
to other chains
Chemical Structure
n
Homopolymer – only one monomer (repeating unit)
- A – A – A – A – A
– A – A -
n
Copolymer – more than one monomer
·
Alternating
- A – B – A – B –
A – B – A – B -
- A – A – B – B –
A – A – B – B -
•
Block
-A-A-A-A-A-B-B-B-B-B-A-A-A-A-A-
-A-A-A-A-A-A-A-B-B-B-B-B-B-B-
·
Graft
B-B-B-B-B-B-B
B
-A-A-A-A-A-A-A-A-A-A-A-A-A-A-A-
B
B-B-B-B-B-B
Classification of Polymers
1. by SOURCES:
1.1 Natural polymers (including
macromolecules)
Polysaccharide: Examples:
starch, glycogen, cellulose, chitin, chitosan
1.2 Synthetic polymers
Examples: plastics, synthetic rubbers, synthetic fibers ect.
2. By skeletal structure
Linear: Monomeric
units are joined in the form of long straight chains, such polymers have high densities,
high tensile strength and high melting point
with two ends.e. g. Polyethylene, nylons and polyesters.
Branched chain: are mainly
linear in nature but also possess some branches along the main chain. E.g. low
density polyethene (LDPE). They have densities, lower tensile strength and low
melting point
Crossed Linked polymers :
Monomeric unit’s are linked together to constitute a three dimensional network.
They are hard, rigid, and brittle. e. g. Bakelite, Melamine formaldehyde resin, etc,
By thermal behavior
The most common way of classifying polymers is to separate them into
three groups - thermoplastics, thermosets, and elastomers5. The thermoplastics
can be divided into two types - those that are crystalline and those that are
amorphous
Thermoplastics are
-relatively weak
intermolecular forces so that the material softens when exposed to heat and
then returns to its original condition when cooled.
-can be repeatedly softened by heating and then solidified by cooling -
a process similar to the repeated melting and cooling of metals.
-
Most linear and slightly branched polymers are
thermoplastic.
-
are produced by chain polymerization.
Thermoplastics have a wide range of applications because they can be formed and
reformed in so many shapes.
-
Some examples are food packaging, insulation,
automobile bumpers, and credit cards.
Recycled plastics
A thermosetting plastic, or
thermoset, solidifies or "sets" irreversibly when heated. -cannot be reshaped by heating.
-usually are three-dimensional networked polymers in which there is a
high degree of cross-linking between polymer chains.
The cross-linking restricts the motion of the chains and leads to a
rigid material. A simulated skeletal structure of a network polymer with a high
cross-link density is shown at the right. --are strong and durable.
They primarily are used in automobiles and construction. They also are
used to make toys, varnishes, boat hulls, and glues.
Elastomers
Elastomers are rubbery polymers that can be stretched easily to several
times their unstretched length and which rapidly return to their original
dimensions when the applied stress is released.
Elastomers are cross-linked, but have a low cross-link density. The
polymer chains still
have some freedom to move, but are prevented from permanently moving
relative to each other by the cross-links.
To stretch, the polymer chains must not be part of a rigid solid -
either a glass or a crystal. An elastomer must be above its glass transition
temperature, Tg, and have a low degree of crystallinity.
Rubber
bands and other elastics are made of elastomers.
By polymerization reaction (for synthetic polymers)
2.1 Condensation polymerization (from
unsaturated hydrocarbons or olefins )
2.2 Chain-growth polymerization (from
unsaturated hydrocarbons or olefins)
3. By
composition
3.1
Homopolymers (contain one type of repeat unit)
3.2Copolymers(contain
at least 2 repeat units)
5. By
application
·
Deformation
·
Stress
·
Strain
Some Special Classes of Concern
Tacticity
q
the way pendant groups are arranged
along the backbone chain of a polymer.
q
particularly significant in vinyl
polymers of the type -H2C-CH(R)
Classification
There are 3 types
q
Isotactic Polymers
o
all the substituent are located on the same
side of the polymer backbone
o
usually semicrystalline
o
often form a helix configuration
o
Example: Polypropylene, formed
by Ziegler-Natta catalysis
q
Syndiotactic Polymers
o
the substituents have alternate positions
along the chain
o
Syndiotactic polystyrene, made
by metallocene catalysis polymerization, is crystalline with
a melting point of 161 °C
q
Atactic Polymers
o
the substituents are placed randomly
along the chain
o
formed by free-radical mechanisms
o
usually amorphous due to their random
nature
o
cannot crystallize and forms
a glass instead
o
most industrial polystyrene produced is atactic
o
Example: polyvinylchloride, polystyrene
q
Eutactic polymers
o
substituents may occupy any specific (but
potentially complex) sequence of positions along the chain
o
Isotactic and syndiotactic polymers are more
general class of eutactic polymers
o
Example: the side-chains in proteins and the
bases in nucleic acids
Polymer Nomenclature
q
generally based upon the type of monomer
residues comprising the polymer
q
Source-based name
- based on name of monomer
- Poly + name of monomer
- ( ) is used if monomer has a multi-worded name
q
Structure-based name
- based on structure of repeat unit
- Poly(name of structure of repeat unit)
Monomer
|
Polymer
|
Structure-based name
|
Source-based name
|
CH2= CH2
|
|
Poly(methylene)
|
Polyethene, Polyethylene
|
|
|
Poly(1-hydroxyethylene)
|
Poly(vinyl alcohol)
|
|
|
Poly(1-methylethylene)
|
Polypropylene, Polypropene
|
IUPAC Recommendation for Source-based Names
q Homopolymer
- Addition polymers
Monomer
|
Polymer
|
Name
|
Uses
|
|
|
Polyethylene (PE)
|
Bags, wire
insulation, squeeze bottles
|
|
|
Polypropylene (PP)
|
Fibers, indoor-outdoor carpets, bottles
|
|
|
Polystyrene (PS)
|
Styrofoam, molded objects such as table
ware (fork, knives, spoon), trays,
video cassette cases
|
|
|
Poly(vinylchloride)
(PVC)
|
Clear food wrap, bottles, floor covering synthetic leather, water & drain pipe
|
|
|
Polytetrafluoroethylene
(Teflon)
|
Nonstick surfaces, plumbing tape, films
|
Types of Polymerization
Addition
Polymerisation
A carbon–carbon double bond is needed in the monomer
A monomer is the small molecule that makes up the polymer
The polymer is the only product
Involves
the opening out of a double bond
The
conditions of the reaction can alter the properties of the polymer
Reaction
proceeds by a free radical mechanism
Oxygen
often used as the initiator
The
board specifies that you know this addition polymerisation reaction
Monomers can add head-to-tail, head-to-head, or
tail-to-tail
Steps of Addition Polymerization
q
Initiation
o
Formation of active site on some monomer.
q
Propagation
o
Chain growth, the addition of an active site to
a growing polymer chain, restoring the active site at the chain end.
q
Termination
o
Destruction of the active growing site.
q
Transfer Reactions
o
Removal of the active site from one chain to
another molecule, terminating the first and beginning propagation at the
second.
Types of Addition Polymerizations
q
Free radical polymerization
o
The initiator is a radical
o
The propagating site of reactivity (*) is a
carbon radical
q
Anionic polymerization
- The initiator is a nucleophile
- The propagating site of reactivity (*) is a carbanion
q
Cationic polymerization
- The initiator is an acid
- The propagating site of reactivity (*) is a carbocation
q
Coordination catalytic polymerization
- The initiator is a transition metal complex
- The propagating site of reactivity (*) is a terminal catalytic complex
Condensation Polymers
q
Involves
2 monomers that have different functional groups.
q
They
also involve the elimination of water or another small molecule.
q
Hence
the term condensation polymer.
q
Monomer
A + Monomer B à
Polymer + small molecule (normally water).
q
Common
condensation polymers include polyesters (the ester linkage) and polyamides (the amide linkage as in
proteins).
Step-growth or Condensation Polymerization
q
Used for
monomers with functional groups such as –OH, – COOH etc.
q
It is
usually a succession of non-catalysed, chemical condensation reactions
associated with the elimination of low molar mass side products, eg., water.
q
Chain
growth is exponential
Maximum
molecular weight is obtained late in the reacti
q
Uses
q
Used to prepare fiber such as polyester.
q
Used for preparing a class of adhesive and
amorphous solids called epoxy resin.
q
Synthetic plastics, which can be reshaped by
heating, are prepared. They are called thermoset.
DP of
Step-growth Polymerization
Because high polymer does not form until the end of the
reaction, high molecular weight polymer is not obtained unless high conversion
of monomer is achieved.
Polyamides
•
These involve the linkage of two monomers through
the amide linkage as in proteins (e.g. silk)
Polymerization Processes
Modern classification of polymerization according to polymerization mechanism
Step growth polymerization: Polymers build up stepwise
Chain growth polymerization: Addition polymerization molecular
weights increase successively, one by one monomer
Ring-opening polymerization may be either step or chain reaction
Carothers equation
( NO : number of molecules
N : total
molecules after a given reaction period.
NO – N
: The amount reacted
P : The reaction
conversion )
Or, N = NO(1 -P)
( DP is the
average number of repeating units of all molecules present)
Comparison of Step-Reaction and Chain-Reaction
Polymerization
Step Reaction
|
Chain Reaction
|
Growth occurs throughout matrix by
reaction between monomers,
oligomers,
and polymers
|
Growth occurs by successive addition of
monomer units to limited
number of
growing chains
|
DPa low to moderate
|
DP can be very high
|
Monomer consumed rapidly while
molecular weight increases
slowly
|
Monomer consumed relatively slowly, but
molecular weight increases
rapidly
|
No initiator needed; same reaction mechanism throughout
|
Initiation and propagation mechanisms different
Usually chain-terminating step involved
|
No termination step; end groups still reactive
|
Usually chain-terminating step involved
|
Polymerization rate decreases steadily as
functional groups consumed
|
Polymerization rate increases initially as
initiator units generated;
remains relatively
constant until monomer
depleted
|
Polymerization Techniques
Sometimes for one monomer several techniques of polymerizing are
available. Choice of a specific technique depends on a number of factors:
Ø
Kinetic
/ mechanistic factors related to chain length, chain composition
Ø
Technological
factors e.g. heat removal, reaction rate, viscosity of the reaction mixture,
morphology of the product
Ø
Economic
factors; production costs, environmental aspects, purification steps etc.
Ø
Bulk Polymerization
Ø
Solution Polymerization
Ø
Suspension Polymerization
Ø
Emulsion Polymerization
Ø
Melt
Polycondensation
Ø
Solution Polycondensation
Ø
Interfacial Condensation
Ø
Solid
& Gas Phase Polymerization
Bulk
(Mass) Polymerization
- The simplest method of polymerization where the reaction mixture contains only the monomer and a monomer soluble initiator.
- Example PMMA
Polymers through step reactions (nylon 6)
q
General Description
Carried
out to high conversion
Free radical kinetics apply
The system is homogeneous
Advantage
of the high concentration of monomer result in
1. High rates of polymerization
2. High
degree of polymerization
3. High
purity of product
4. High
molar mass polymer are produce
Advantages Disadvantages
*
Pure products * heat control
*
Simple equipment *
dangerous
* No organic solvents * molecular weight is very
disperse
Process Schemes
- Initiator is dissolved in liquid monomer.
- Chain transfer agent, whenever used to control MW, is dissolved in monomer itself.
- Reaction mass is heated or exposed to radiation source for initiation & kept under
agitation for proper mass
& heat transfer.
- Achieve low conversion in large reactor, then prepare slabs or films.
- Uses
- Used for ethylene, styrene, methyl methacrylate to get transparent moulding powders and casting sheetings
- Used for vinyl chloride to get PVC resin.
Solution
Polymerization
This method is used to solve the problems
associated with the bulk polymerization because the solvent is employed to
lower the viscosity of the reaction, thus help in the heat transfer and reduce
auto acceleration.
General Description
- Homogeneous, if polymer remains soluble
Ø
vinyl
acetate
Ø
acrylonitrile
Ø
esters of
acrylic acid
- Heterogeneous, if polymer is insoluble, leading to precipitation (powder or granular) polymerization:
Ø
acrylonitrile in water
Ø
vinyl
chloride in bulk
Free radical
kinetics apply
Process Schemes
- Monomer is dissolved in suitable inert solvent
- Free radical initiator dissolved in solvent medium, the ionic & coordination catalysts can either be dissolved or suspended.
- Presence of inert solvent medium helps to control viscosity increase & promote a proper heat transfer.
q
Advantages
o
Solvent acts as a diluent and aids in removal of
heat of polymerization.
o
Solvent reduces viscosity, making processing
easier.
o
Thermal control is easier than in the bulk
q
Disadvantages
o
Chain transfer to solvent occurs, leading to low
molecular weights.
o
Difficult to remove solvent from final form,
causing degradation of bulk properties.
o
Environmental pollution due to solvent release
q
Uses
o
Industrial production of polyacrylonitrile by
free-radical polymerization
o
Production of polyisobutylene by cationic
polymerization
o
Block co-polymers are exclusively made by this
technique.
Suspension (Bead) Polymerization
This method is used also to solve the problem
of heat transfer.
It is similar to bulk polymerization where the
reaction mixture is suspended as droplets in an inert medium.
Monomer, initiator and polymer must be
insoluble in the suspension media such as water
Water insoluble monomers are
dispersed in water.
Initiator dissolved in monomer.
Stabilization of droplets/polymer
particles with non-micelle forming emulsifiers like polyvinylalcohol or Na-carboxymethylcellulose.
Equivalent to bulk polymerization,
small droplets dispersed in water.
Product can easily be separated,
particles 0.01-1mm.
Pore sizes can be controlled by
adding a combination of solvent (swelling agent) and non-solvent.
Viscosity does not change much.
General Description
- Droplets are 0.001-1 cm in diameter.
- Kinetics are the same as in the bulk.
- Must have very low monomer solubility in water or polymer will form in aqueous phase.
Advantages
- Low viscosity due to the suspension
- Easy heat removal due to the high heat capacity of water
- Polymerization yields finely divided, stable latexes and dispersions to be used directly in coatings, paints, and adhesives.
Disadvantages
- Cannot be used for polymers whose glass transition temperature is less than the polymerization temperature, or else aggregation will occur.
- Must separate and purify polymer, or accept contaminated product.
Uses
- Used for
- Polystyrene beads (from which polystyrene foams are made)
- Styrene-divinyl benzene co-polymer beads (for preparation of ion-exchange resin)
- Polyvinyl acetate beads (for conversion into polyvinyl alcohol)
Emulsion
Polymerization
This is similar to suspension
polymerization except that the initiation is soluble in suspension media and insoluble in the monomer.
The reaction product is
colloidally stable dispersion known as latex.
The polymer particles have
diameter in the range of (0.05 - 1 m m) smaller than suspension.
General Description
- Surfactant is aggregated in micelles.
- Monomer is stabilized by surfactant and dispersed in water.
- Predominant process for vinyl acetate, chloroprene,butadiene/styrene/acrylonitrile
copolymers,
various acrylates.
- Used somewhat for methyl methacrylate, vinyl chloride, vinylidene chloride, styrene.
Advantages
- Thermal and viscosity problems are minimized due to the high heat capacity and ease of stirring of the continuous aqueous phase.
- Molecular weight may be increased without decreasing RP
- Recall that in normal free-radical polymerization RP and Xn are inversely related:
- The latex may be used directly without purification.
Melt
Polycondensation
q
General Description
o
Homogeneous system
o
Used for polymerization of monomers having at
least one solid component & do not decompose around their melting point.
q
Advantages
o
No exotherm.
o
Suitable for producing medium to high molecular
weights products.
Product minimum contaminated.
q
Disadvantages
- Requires longer duration for very high conversions.
- Viscosity of the medium increases very rapidly and at high conversions, proper mass transfer becomes difficult.
- Removal of by-product becomes difficult at high conversions.
- Proper heat transfer within the medium becomes difficult at high conversions.
q
Uses
- Production of polyethylene terephthalate from dimethyl terephthalate and ethylene glycol
- Preparation of nylon 6,6
Solution
Polycondensation
q
General Description
o
Homogeneous system
o
System becomes heterogeneous, if the polymer is
insoluble in the solvent.
o
Viscosity of the medium increases slowly.
q Advantages
o
Reaction can be carried out at lower temperature
and heat and mass transfer process become easier.
o
No
exotherm. Heat transfer is uniform.
o
Removal of by-product is comparatively easier if
a suitable solvent is chosen as entrainer.
o
Suitable for producing medium to high molecular weight products.
q
Disadvantages
o
Requires longer duration for very high
conversions.
o
Kinetic probability of chain growth is low and this leads to a reduced rate and a low
degree of polymerization.
o
Product usually contaminated with solvent.
o Uses
o Liquid
polymer resins based on glycols and unsaturated dicarboxylic acid are prepared.
IONIC POLYMERIZATION
Chain polymerization of
olefinic monomers which can occur with charged radicals. For example styrene.
Cationic polymerization when
the radical is positively charge.
CH2-C+H
X
Anionic polymerization when the
radical is negatively charge
CH2-C--H
X
This polymerization is more
monomer specific than free radical polymerization and will proceed only with
monomers that have substituent groups which can stabilize the active center.
For cationic polymerization the
active center will proceed if X group is able to donate electrons or delocalize
the positive charge.
For anionic polymerization the
active center will proceed if X group is able to withdraw electrons or
delocalize the negative charge.
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