Module 5: Polymers, Conducting Polymers, and Nanomaterials PDF

Summary

This document is a set of lecture notes covering various topics related to polymers, conducting polymers, and nanomaterials. It discusses the synthesis, application, and properties of different types of polymers like ABS and Bakelite and also different types of nanomaterials including gold nanoparticles. The document also explores different processes of synthesizing polymers and nanomaterials including top-down and bottom-up approaches.

Full Transcript

Winter semester 2023-2024

Module-5

 Polymers (ABS and BAKELITE)- synthesis and application
 Conducting polymers- polyacetylene and effect of doping
 Nanomaterials – introduction, Bulk Vs Nano (Gold)
 Top-down and bottom-up approaches for synthesis, and

1
 Types of Plastics
Plastics are classified into two types………..
1. Thermoplastic
2. Thermosetting resins

1. Thermoplastic
Thermoplastics are the plastics that do not undergo chemical change in
their composition when heated and can be molded again and again.

 They are prepared by addition polymerisation.
 They are straight chain (or) slightly branched polymers and
 Various chains are held together by weak vanderwaal’s forces of attraction.
 It can be softened on heating and hardened on cooling reversibly.
 They are generally soluble in organic solvents
Examples: Polyethylene, Polyvinylchloride

 Common thermoplastics range from 20,000 to 500,000 amu
 Each polymer chain will have several thousand repeating units.

They can be recycled and reused many times by heating and cooling
process.
2. Thermosetting resins or Thermosets
 Thermosetting resins can melt and take shape once; after they have
solidified, they stay solid.
 They are prepared by condensation polymerisation.
 Various polymer chains are held together by strong covalent bonds
(cross links)
 These plastics get harden on heating and once harden, they cannot be
softened again.
 They are almost insoluble in organic solvents.

Examples: Bakelite, Polyester

Thermoset Polymers whose individual chains have been chemically cross
linked by covalent bonds and form a 3-D cross linked structure.

 Therefore, they resist heat softening and solvent attack.
 These are hardened during the molding process and once they are cured,
they cannot be softened and they cannot be recycled and reused

Eg. Phenol-formaldehyde resins, urea-formaldehyde paints.
Difference between Thermoplastic and Thermosetting Polymers………

Thermoplastic polymers Thermosetting polymers
Consists of long-chain linear polymers Have 3-Dimensional network structures
with negligible cross-links. joined by strong covalent bonds.

Soften on heating readily because Do not soften on heating; On prolonged
secondary forces between the individual heating, they are charred.
chain can break easily by heat or pressure.

By re-heating to a suitable temperature, Retain their shape and structure even on
they can be softened, reshaped and thus heating. Hence, cannot be reshaped.
reused.

Usually soft, weak and less brittle. Usually, hard, strong and brittle.

Can be reclaimed from wastes. Cannot be reclaimed from wastes.

Usually soluble in some organic solvents. Due to strong bonds and cross-linking,
they are insoluble in almost all organic
solvents.
Properties and engineering applications

Types of Thermoplastic resins:
Vinyl resins.. Examples:
(i) PVC
(ii) TEFLON or FLUON
(iii)ABS (Acrylonitrile Butadiene Styrene)

Types of Thermosetting resins:

Phenolic resins or phenoplasts
(iv)Novolac
(v) Bakelite
 Acrylonitrile-Butadiene-Styrene (ABS) Plastics

Properties
ABS is an opaque
thermoplastic and
amorphous polymer. Applications
It can be easily recycled and Among the most widely
relatively non-toxic. identifiable are keys on a
ABS has a strong resistance computer keyboard, power-tool
to corrosive chemicals housing, the plastic face-guard
and/or physical impacts. on wall sockets (often a PC/ABS
It is very easy to mold and blend), and LEGO toys.
has a low melting ABS is used for 3D Printing and
temperature making it Prototype Development.
particularly simple to use in Also, it is used in camera
injection molding housings, protective housings, 6
manufacturing processes or
 Thermosetting Plastics:
(a) Phenolic resins or Phenoplasts : Novoloc and
Bakelite
Phenolic resins are condensation polymerization products of
phenol derivatives and aldehydes.
At first, Phenol reacts
with Formaldehyde in
presence of acidic /
alkaline catalyst to form
Monomethylnol phenol.

Monomethylol phenol
further reacts with Phenol
to form a linear polymer
“Novolac”.

Water is removed as the
Novolac by-product.
 Thermosetting Plastics: Bakelite

 Further addition of HCHO at high
temperature and pressure converts
Novolac (soft and soluble) into cross-
linked “Bakelite” (hard and insoluble).

Bakelite
 Bakelite
Properties:

 Bakelite is resistant to acids, salts and most organic solvents, but it is
attacked by alkalis because of the presence of –OH groups.

 It possesses excellent electrical insulating property.

 As thermoset it is difficult to recycle.

Uses:

 Bakelite is used as an adhesive in plywood laminations & grinding
wheels, etc

 It is also widely used in paints, varnishes,

 It is used for making electrical insulator parts like plugs, switches, heater
handles, paper laminated products, thermally insulation foams etc.
 Conducting Polymers

Polymers, particularly those with a conjugated p-bond structure often
show higher conductivity when doped with conductive materials.
But the use of conductive polymers is limited since they have poor
mechanical strength.
Hence, a combination of mechanical and electrical properties can only
find good applications in conductive polymers area.
Sometimes, in a polymer blend, a bifunctional linker is doped to
increase the conductivity of Polyaniline (PANI) (having conductivity) and
polycaprolactum (PCL) (having mechanical strength) blend.
Conductive polymers can be made using simple procedures like melt
blending, solution blending etc., and can be used for antistatic and
electromagnetic shielding applications.
10
Some Examples of Conductive Polymers

11
 Mechanism of Conduction in Polymers

Conjugation of -
electrons
Undoped Insulating

Conducting
Doped
+
A- Dopant anion for charge neutrality

12
Different Types of Conducting Polymers:
1. Intrinsically conducting polymers (ICP)
2. Doped Conducting polymers
3. Extrinsically conducting polymers (ECP)

Factors that affect the conductivity:
1. Density of charge carriers
2. Their mobility
3. The direction
4. Presence of doping materials (additives that
facilitate the polymer conductivity in a better way)
5. Temperature 13
1. Intrinsically Conducting Polymers (ICPs)
 Polymer consisting of alternating single and double bonds
is called conjugated double bonds.
 In conjugation, the bonds between the carbon atoms are
alternately single and double. Every bond contains a
localised “sigma” (σ) bond which forms a strong chemical
bond.
 In addition, every double bond also contains a less
strongly localised “pi” (π) bond which is weaker.
 Conjugation of sigma and pi-electrons over the entire
backbone, forms valence bands and conduction bands.
Eg: Poly-acetylene, poly-p-phenylene, polyaniline, polypyrrole
polymers

Polyacetylene
14
 Doped Conducting Polymers
 ICPs possess low ionisation potential and high
electron affinity. So they can be easily
oxidised or reduced.
 The conductivity of ICP can be increased by
creating positive charges (oxidation) or by
negative charges (reduction) on the polymer
backbone.
 This technique is called DOPING.
 There are two types of doping:
p-doping achieved by oxidation
n-doping achieved by reduction
 p-Doping
 p-doping is achieved by oxidation process. It is
also known as the oxidative doping.
 It involves treatment of an polyacetylene with
a Lewis acid or iodine which leads to oxidation
process and positive charges on the polymer
backbone are created.
 Some of the p-dopants are I2, Br2, AsF5, FeCl3,
HClO4, PF5 etc.

(CH)x + 2 FeCl3 → (CH)x+. FeCl4- + FeCl2
2 (CH)x + 3 I2 → 2 (CH)x+. I3-
 This oxidation process or removal of one
electron leads to the formation of delocalized
radical ion called polaron
 n-Doping
 n-doping is achieved by reduction process. It is
also known as the reductive doping.
 It involves treatment of an polyacetylene with a
Lewis base which leads to reduction process and
negative charges on the polymer backbone are
created.
 Some commonly available n-dopants are Li, Na,
Ca, sodium naphthalide, etc.

(CH)x + Li → Li+(CH)x-. + C10H8
(CH)x + Na+ Na+ (CH)x +

 This reduction process or the donation of one
electron leads to the formation of delocalized
radical anion, an anioninc polaron
 Doping in ICP
p-doping n-doping

-e I 2/ CCl 4 -e Na+(C10H 8)-.

Polaron Polaron
-e I 2/ CCl 4 -e Na+( C10H 8)-.

Bipolaron Bipolaron
Segregation of cation Segregation of anion

Soliton Soliton

 What is a soliton? The soliton is a charged or a
neutral defect in the polyacetylene chain that
propagates down the chain, thereby reducing
In p-type doping, the dopant (Iodine, I2) attracts an
electron from the polyacetylene chain to form (I3-) leaving
a positive soliton (carbenium ion) in the polymer chain
that can move along its length.
The lonely electron of the double bond, from which an
electron was removed, can move easily.
As a consequence, the double bond successively moves
along the molecule, and the polymer is stabilized by
having the charge spread over the polymer chain.

Doping in Trans-Polyacetylene 19
Conductivity Mechanism in Polyacetylene:
The mechanism followed by polyacetylene for the transfer of charge from one
chain to another is called intersoliton hopping.
What is a soliton? The soliton is a charged or a neutral defect in the
polyacetylene chain that propagates down the chain, thereby reducing the barrier
for interconversion.
In n-type doping (This can be
done by dipping the film in
THF solution of an alkali
metal) soliton is a resonance-
stabilized polyenyl anion of
approximately 29-31 CH units
in length, with highest
amplitude at the centre of the
defect.
The solitons (anions) transfer
electrons to a neutral soliton
(radical) in a neighboring
chain through an isoenergetic
process.
The charged solitons are
responsible for making
polyacetylene a conductor.20
 3. Extrinsically Conducting Polymers
These are those polymers whose conductivity is due to the presence
of externally added ingredients in them.
Two types:
(1) Conductive element filled polymer:
 It is a resin/polymer filled with carbon black, metallic fibres, metal
oxides etc. Polymer acts as a binder to those elements.
 These have good bulk conductivity and are low in cost, light
weight, strong and durable. They can be in different forms,
shapes and sizes.
(2) Blended Conducting Polymers:
 It is the product obtained by blending a conventional polymer
with a conducting polymer either by physical or chemical change.
 Such polymers can be processed and possess better physical,
chemical and mechanical strength.
21
§ Introduction to Nanomaterials
A nanoparticle is an entity with a width of a few nanometers to a few
hundred, containing tens to thousands of atoms. Their defining
characteristic is a very small feature size in the range of 1-100 (nm).

Nano size:
One nanometre is a millionth part of the size of the tip of a needle.
1 nm = 10-6 mm = 10-9 m
Table 1. Some examples of size from macro to molecular
Size Examples Terminology
(nm)
0.1-0.5 Individual chemical bonds Molecular/atomic
Bulk Gold
0.5-1.0 Small molecules, pores in Molecular
zeolites
1-1000 Proteins, DNA, inorganic Nano
nanoparticles From: USDA’s
103-104 living cells, human hair Micro roadmap of
nanotechnology.
>104 Normal bulk matter Macro
22
 Size and shape dependent colors of Au and Ag nanoparticles
Gold NPs in Glass Silver NPs in Glass
25 nm
100 nm
Sphere
Sphere
reflected
reflected

50 nm 40 nm
Sphere Sphere
reflected reflected

100 nm
100 nm prism
Sphere reflected
reflected

23
23
 Size and shape dependent colors of Au and Ag nanoparticles

: nanomaterials scatter visible light rather than absor
tance between particles also effects colour

Surface plasmon resonance: Excitation of surface plasmons by light (visible
or infra red) is denoted as a surface plasmon resonance
Localized surface plasmon resonance (LSPR) for nanometer-sized metallic structures
24
24
 What are surface plasmons ?
 When an electromagnetic radiation interacts with metal
nano particles ( e.g. Au & Ag) present in a dielectric
medium, it induces a collective oscillation of conduction
electrons called surface plasmons.
 It can be studied by the UV-Visible spectrum of the
nano particles
Applications: diagnostics and  Surfaceof biomolecular
analysis plasmon
interactions etc. resonance spectrum
can be simulated by
Mie theory
 It helps to arrive at the
particle size of the nano
particles.
 The adjacent figure
shows the experimental
spectrum and the
Categories of Nanomaterials

26
 Quantum Dots and applications
Quantum dots (QDs) are semiconductor particles of few nanometers ( red reflected
50 nm > green reflected
100 nm > orange reflected

4 Is metallic, with a yellow colour when in Are not “metals” but are semiconductors
a mass (Band gap energy = 3.4 eV)
5 Good conductors of heat and electricity Are very good catalysts
6 Generally have high densities
7 Have high melting point (~1080oC) Melts at relatively low temp (~940º C)
8 Are often hard and tough with high
tensile strength
9 Having high resistance to the stresses of
being stretched or drawn out
10 Not easily breakable
11 Inert-unaffected by air & most reagents
32
33
 Schematic representation of the ‘bottom up’ and top down’
synthesis processes of nanomaterials

High-energy By
wet ball milling atom-by-atom
molecule-by-molecule
cluster-by-cluster
Less waste
More economical

34
Any fabrication technique should provide the followings:
Identical size of all particles (also called mono sized or with
uniform size distribution
Identical shape or morphology
Identical chemical composition and crystal structure
Individually dispersed or mono dispersed i.e., no
agglomeration

35
 Nanoparticles preparation:
 Top-down approaches
 High-energy ball milling/Machining
 Chemical Oxidation Process (CNTs to QDs)
 Electrochemical Oxidation Process (Graphite rod to QDs)
 Lithography (photo- and electrochemical)
 Etching/Cutting
 Coating
 Atomization
Bottom-up approaches
Gas Condensation Processing (GCP)/Aerosol­Based Processes
 Chemical Vapour Condensation (CVC)
 Atomic or Molecular Condensation
 Laser ablation
 Supercritical Fluid Synthesis
Wet Chemical Synthesis of nanomaterials (Sol-gel process)
 Precipitation method
 Spinning
 Self-Assembly
36
 DNA Origami
Schematic representation of the principle of mechanical milling

WC coated
50 µm powder ball

37
 Mineral, ceramic processing, and powder metallurgy industry
 Procedure of milling process
 Particle size reduction, solid-state alloying, mixing or blending, and
particle shape changes
 Restricted to relatively hard, brittle materials which fracture and/or

deform and cold weld during the milling operation
 To produce nonequilibrium structures including nanocrystalline,
amorphous and quasicrystalline materials
 Users are tumbler mills, attrition mills, shaker mills, vibratory mills,
planetary mills etc
 Powders diameters of about 50 µm with a number of hardened steel or
tungsten carbide (WC) coated balls in a sealed container which is
shaken or violently agitated. The most effective ratio for the ball to
powder mass is 5 : 10. 38
 Shaker mills (e.g. SPEX model 8000) uses small batches of powder
(approximately 10 cm3 is sufficient

 Advantage: High production rates
 Limitation
 Severe plastic deformation associated with mechanical attrition due to
generation of high temp in the interphase, 100 to 200 oC.
 Difficulty in broken down to the required particle size
 Contamination by the milling tools (Fe) and atmosphere (trace
elements of O2, N2 in rare gases) can be a problem (inert condition
necessary like Glove Box)(Fe 10%)
39
Wet Chemical Synthesis of nanomaterials (Sol-gel
SOL - nanoparticle dispersion
process)
GEL - crosslinked network

Thermal
evaporation
Calcine

800oC

Schematic representation of sol-gel process of synthesis of nanomaterials.
40
41
 Overall Steps:
Step 1: Formation of different stable solutions of the alkoxide (the sol).

Step 2: Gelation resulting from the formation of an oxide- or alcohol-bridged
network (the gel) by a polycondensation or polyesterification reaction

Step 3: Aging of the gel, during which the polycondensation reactions continue
until the gel transforms into a solid mass, accompanied by contraction of the
gel network and expulsion of solvent from gel pores.

Step 4: Drying of the gel, when water and other volatile liquids are removed
from the gel network.

– If isolated by thermal evaporation, the resulting monolith is termed a
xerogel.
– If the solvent (such as water) is extracted under supercritical or near
super critical conditions, the product is an aerogel.

Step 5: Dehydration, during which surface- bound M-OH groups are removed,
thereby stabilizing the gel against rehydration. This is normally achieved by
calcining the monolith at temperatures up to 8000C.

Step 6: Densification and decomposition of the gels at high temperatures
(T>8000C). The pores of the gel network are collapsed, and remaining organic
species are volatilized. The typical steps that are involved in sol-gel processing
are shown in the schematic diagram above. 42
 Sol/gel transition controls the particle size and shape. Calcination of
the gel produces the product (eg. Oxide).
Sol-gel processing > hydrolysis and condensation of alkoxide-based
precursors such as Si(OEt)4 (tetraethyl orthosilicate, or TEOS).
The reactions are as follows:
MOR + H2O → MOH + ROH (hydrolysis)
MOH+ROM→M-O-M+ROH (condensation)
If the aging process of gels exceeds 7 days it is critical to prevent the
cracks in gels that have been cast
Steps are:
Sol Gel Ageing Drying Dehydration
Densification & Decomposition Product

43
 Advantages
Synthesizing nonmetallic inorganic materials like glasses, glass
ceramics or ceramic materials at very low temperatures compared to
melting glass or firing ceramics
Monosized nanoparticles possible by this bottom up approach.
 Disadvantages
Controlling the growth of the particles and then stopping the newly
formed particles from agglomerating.
Difficult to ensure complete reaction so that no unwanted reactant is
left on the product
Completely removal of any growth aids
Also production rates of nanopowders are very slow by this process

44
 e-Book for Nanomaterials
https://drive.google.com/file/d/18Giu
eZtfwNd5atOi5V8sijg9oqR-LvjM/view
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