Chapter 9 Powerpoint

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Transcript Chapter 9 Powerpoint

Chapter 9: The World of Polymers and Plastics
Why is plastic so important?
What happens to
recycled
plastics and polymers?
Are there downsides to
recycling?
What do you think of when you hear the word “plastic”?
Rayon
Nylon
Lycra
polyurethane
Teflon
Styrofoam
Saran
Plastics are polymers. What is a polymer?
Polymers are large molecules made up of long chains of atoms
covalently bonded together.
Monomers (from mono meaning “one” and meros meaning
“unit”) are the small molecules used to synthesize the polymeric
chain, like a strand of paper clips.
9.2
Polymers have been with us since the beginning of time.
Natural polymers include such things as cellulose, starch, tar and
shellac, tortoise shell and horns, as well as tree saps that produce
amber and latex.
These polymers were processed with heat and pressure into useful
articles like hair ornaments and jewelry.
Natural polymers began to be chemically
modified during the 1800s to produce
many materials. The most famous of these
were vulcanized rubber, cotton, and
celluloid.
The first semi-synthetic polymer produced was Bakelite in 1909
and was soon followed by the first synthetic fiber, rayon, which
was developed in 1911.
9.2
The polymers (poly means “many”) can be formed from the
same type of monomer or from a combination of monomers:
(a) A representation of a monomer.
(b) A representation of a polymer made of one monomer.
(c) A representation of a polymer made of two different monomers.
9.3
Polymers are referred to as macromolecules because they
involve thousands of atoms, and their molecular masses can
reach over a million.
Many common classes of polymers are composed of hydrocarbons.
Carbon makes up the backbone of the molecule and hydrogen atoms
are bonded to the carbon atoms. Below is a diagram of polyethylene,
the simplest polymer structure.
H
H
H
C
H
H
C
*
C
C
H
C
H
H
H
*
H
n
polyethylene
Other examples of polymers that contain only carbon and
hydrogen include polypropylene, polybutylene, and polystyrene.
9.3
In addition polymers, the monomers simply add to the growing
polymer chain in such a way that the product contains all the
atoms of the starting material.
H
H
2
C
C
H
H
ethylene
monomer
H
H
H
H
C
C
C
C
H
H
H
H
addition product
As additional ethylene molecules join, the chain grows:
H
H
C
H
C
+
R
H
H
H
H
H
H
H
H
H
H
C
C
C
C
C
C
C
C
C
C
H
H
H
H
H
H
H
H
H
H
No other products are formed, and no atoms are eliminated.
9.3
The overall process can be represented as:
H
n
H
H
C
C
H
H
H
C
C
H
H
n
If one of the H atoms on ethylene is replaced with a Cl atom,
H
n
H
C
C
H
Cl
H
C
H
H
C
Cl
n
the result is the formation of polyvinyl chloride (PVC).
9.3
Formation of Polyethylene (PE): Mechanism
A free-radical process, initiated by a catalyst
9.3
Stretching or “necking” a plastic bag
Pulling on a piece of PE
Represents the molecular
rearrangement as PE is stretched
Dispersion forces (intermolecular forces) are attractions between
molecules in the polymer that hold the material together
9.4
Branching alters the physical properties of PE
Straight chain
Branched
chain
Low density
PE (LDPE) –
soft, stretchy,
not too strong
High density PE (HDPE) – greater rigidity, strength, higher mp
9.4
There are over 60,000 synthetic polymers today. Here are 3 of
the most common polymers known collectively as the “Big Six”:
9.5
Three more polymers that make up the “Big Six”
How do we make sense of these representations?
What makes one polymer different from another?
9.5
Many different arrangements are possible when a polymer forms
from polyvinylchloride (PVC) monomers
How do these different arrangements affect the properties of the polymer?
9.5
H
n
H
H
C
C
H
C
C
H
styrene monomer
H
n
The polystyrene foam used for Styrofoam cups is
made by the same addition process.
9.5
One way to
differentiate
between
polymers is to
look at their
functional
groups distinctive
arrangements of
atoms that impart
characteristic
chemical
properties to the
molecules that
contain them.
9.6
Condensation Polymers
Formation of PET
Ester linkages
highlighted in blue
Examples
Natural: starch, wool, silk, proteins
Synthetic: nylon, kevlar, and ABS
9.6
Proteins are long chains of amino acids joined
by condensation polymerization
Peptide Bond- covalent bond that forms between –COOH group of
one amino acid and the -NH2 group of the next
9.7
Nylon is another common example of a condensation polymer
9.7
Composition of municipal solid waste:
100 billion pounds of plastic is produced in the U.S. each
year- much of this ends up in landfills.
9.9
Recycling plastics:
Even though we are recycling more plastic that ever in the U.S.
We recycle less plastic by percentage (1 in 5 plastic soda
bottles in 2010 vs. 1 in 3 in 1995).
9.9
Recycling Involves a Never-Ending Loop:
9.9
Plastics from Renewable Materials:
Consumer products made from polylactic acid (PLA)
9.10