PEX is a
medium- to high-density polyethylene containing
cross-link bonds introduced into the polymer
structure, changing the thermoplast into an
elastomer. The high-temperature properties of
the polymer are improved, its flow is reduced and
its chemical resistance is enhanced.
MDPE is defined by a density range of
0.926 - 0.940 g/cc. MDPE can be produced by
chromium/silica catalysts, Ziegler-Natta catalysts
or metallocene catalysts.
LLDPE is defined by a density range of
0.915 - 0.925 g/cc. is a substantially linear
polymer, with significant numbers of short branches,
commonly made by
copolymerization of ethylene with short-chain
alpha-olefins (e.g. 1-butene, 1-hexene, and
1-octene.
LDPE is defined by a density range of
0.910 - 0.940 g/cc. LDPE has a high degree of short
and long chain branching, which means that the
chains do not pack into the
crystal structure as well. It has therefore less
strong intermolecular forces as the
instantaneous-dipole induced-dipole attraction
is less. This results in a lower
tensile strength and increased
ductility. LDPE is created by
free radical
polymerization. The high degree of branches with
long chains gives molten LDPE unique and desirable
flow properties.
VLDPE is defined by a density range of
0.880 - 0.915 g/cc. is a substantially linear
polymer, with high levels of short chain branches,
commonly made by
copolymerization of ethylene with short-chain
alpha-olefins (e.g. 1-butene, 1-hexene, and
1-octene. VLDPE is most commonly produced using
metallocene catalysts due to the greater co-monomer
incorporation exhibited by these catalysts.
The most common household use of HDPE is in
containers for
milk, liquid
laundry detergent, etc; the most common
household use of LDPE is in
plastic bags. LLDPE is used in flexible tubing
and in bags either neat or blended with LDPE.
HDPE is also widely
used in the
fireworks community. In tubes of varying length
(depending on the size of the ordinance), HDPE is
used as a replacement for the supplied cardboard
mortar tubes for two primary reasons. One, it is
much safer than the supplied cardboard tubes because
if a shell were to malfunction and explode inside (flower
pot) an HDPE tube, the tube will not shatter.
The second reason is that they are reusable allowing
designers to create multiple shot
mortar racks. All
pyrotechnicians discourage the use of
PVC tubing in mortar tubes because it will
shatter, sending
shards of plastic at possible
spectators, and will not show up in
x-rays.
Recently, much research activity has focused on
the nature and distribution of Long Chain
Branches in polyethylene. These branches are
present in all polyethylenes to some degree, and are
very common in LDPE. In HDPE however, a relatively
small number of these branches (perhaps 1 in 100 or
1000 branches per backbone carbon) can significantly
affect the
rheological properties of the polymer.
History
Polyethylene was first
synthesized by the
German chemist
Hans von Pechmann, who prepared
it by accident in 1898 while heating
diazomethane. When his
colleagues
Eugen Bamberger and
Friedrich Tschirner
characterized the white, waxy
substance he had created, they
recognized that it contained long
-CH2- chains and termed
it polymethylene.
The first industrially practical
polyethylene synthesis was
discovered (again by accident) by
Eric Fawcett and
Reginald Gibson at
ICI Chemicals in 1933. Upon
applying extremely high pressure
(several hundred atmospheres) to a
mixture of ethylene and
benzaldehyde, they again
produced a white waxy material.
Since the reaction had been
initiated by trace
oxygen contamination in their
apparatus, the experiment was at
first difficult to reproduce. It was
not until 1935 that another ICI
chemist,
Michael Perrin, developed this
accident into a reproducible
high-pressure synthesis for
polyethylene that became the basis
for industrial LDPE production
beginning in 1939.
Subsequent landmarks in
polyethylene synthesis have centered
around the development of several
types of
catalyst that promote ethylene
polymerization at more mild
temperatures and pressures. The
first of these was a
chromium trioxide based catalyst
discovered in 1951 by
Robert Banks and
John Hogan at
Phillips Petroleum. In 1953, the
German chemist
Karl Ziegler developed a
catalytic system based on
titanium
halides and organoaluminum
compounds that worked at even milder
conditions than the Phillips
catalyst. The Phillips catalyst is
less expensive and easier to work
with, however, and both methods are
used in industrial practice.
By the end of the 1950s both the
Phillips and
Ziegler type catalysts were
being used for HDPE production.
Phillips' initially had difficulties
producing a HDPE product of uniform
quality, and filled warehouses with
off-specification plastic. However,
financial ruin was unexpectedly
averted in 1957, when the
hula hoop, a toy consisting of a
circular polyethylene tube, became a
fad among teenagers throughout the
United States.
A third type of catalytic system,
one based on
metallocenes, was discovered in
1976 in Germany by
Walter Kaminsky and
Hansj
rg Sinn. The Ziegler and
metallocene catalyst families have
since proven to be very flexible at
copolymerizing ethylene with other
olefins and have become the
basis for the wide range of
polyethylene
resins available today,
including
VLDPE, and
LLDPE. Such resins, in the form
of fibers like
Dyneema, have (as of 2005) begun
to replace
aramids in many high-strength
applications.
Until recently, the metallocenes
were the most active single-site
catalysts for ethylene
polymerisation known - new catalysts
are typically compared to
zirconocene dichloride. Much effort
is currently being exerted on
developing new single-site
(so-called
post-metallocene) catalysts,
that may allow greater tuning of the
polymer structure than is possible
with metallocenes. Recently, work by
Fujita at the
Mitsui corporation (amongst
others) has demonstrated that
certain salicylaldimine complexes of
Group 4 metals show
substantially higher activity than
the metallocenes.
