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. . . Is about optimizing technology
A polymer is a chain of small molecules joined together in a repeating
fashion to form a single layer molecule. Chemists develop polymers so
they can be used to make ingredients for products with unique physical
and chemical properties. They manipulate large, complex molecules and
capitalize on the connections between their molecular structure and the
properties that make them useful. Polymer products can be lightweight,
hard, strong, and flexible and have special thermal, electrical, and optical
characteristics; they include products from the fiber, communication,
packaging, and transportation industries.
The big boom in polymer chemistry occurred largely in the first part
of the twentieth century with the advent of polymer materials such as
nylon and Kevlar®. Today, most work with polymers focuses on improving
and fine-tuning existing technologies. Still, there are opportunities
ahead for polymer chemists. They work in many industries, creating a variety
of synthetic polymers such as Teflon® and special application plastics
and developing new polymers that are less expensive or that outperform
traditional materials and replace those that are scarce.
"The world is changing," says James Shepherd, a research associate
in polymer chemistry at Hoechst Celanese. "New demands for polymer
materials will be coming down the line. What we have learned over the
past ten years will enable us to fulfill new needs. We may not discover
a new polyethylene," he says, "but we may find smaller-volume
and potentially more cost-effective materials."
. . . Is about research and business
There has been a shift in the economic emphasis and focus of polymer chemistry.
Shepherd says when he began working in the field, many projects were purely
exploratory. "Only later would we worry about the product."
Now, projects are evaluated at the outset on the basis of what they will
do for the company and what end-use improvements they will deliver. Therefore,
industrial polymer chemists are increasingly in contact with the sales
and marketing divisions of their companies and its customers.
This shift has placed a premium on good communication and interpersonal
skills. It means chemists must adopt a business outlook in their work.
Other skills and disciplines also come into play. "It helps if you
are engineering-minded," says Kate Faron, a senior research chemist
at DuPont. John Droske, professor of chemistry at the University of Wisconsin-Stevens
Point, agrees. "This is a field for people who are comfortable looking
at the end use as well as the preparation."
Polymer chemistry is product-oriented. However, this does not eliminate
the availability of positions outside of industry. Some polymer chemists
pursue their research interests in addition to their teaching and administrative
responsibilities through employment at colleges and universities.
. . . Touches many scientific disciplines
Polymer chemistry touches many scientific disciplines and is vital in
fields that develop products such as plastics and synthetic fibers; agricultural
chemicals; paints and adhesives; and biomedical applications such as artificial
skin, prosthetics, and the nicotine patch that helps smokers overcome
their smoking habit. It is estimated that as many as 50% of all chemists
will work in polymer science in some capacity during their careers. Because
they work in a field that is so broad, polymer chemists must be flexible
and be able to interact and communicate with others in a variety of disciplines.
Because polymer chemistry today is product oriented, it has some overlap
with materials science. However, polymer chemists emphasize that the most
important aspect of their work is in the organic synthesis of materials.
Most Ph.D. chemists now in the field were trained in organic chemistry.
They acknowledge the strengths of degree programs in polymer science,
but many say they would still choose to obtain a solid background in organic
chemistry before entering the polymer science area. "You should take
polymer classes, but not without a strong foundation in organic chemistry,"
says Jim Mason, senior chemist in the polymers division at the Bayer Corporation.
"You learn a lot on the job," he adds. He says that an employer
can teach you about polymers, but the fundamentals should be learned while
in school. Mason adds, "Traditional training may also provide you
with more long-term job security." Faron says, "It helps to
be a generalist. If you go into certain polymer programs, you could be
specializing too soon."
. . . Is a field open to change
"Things in the area of polymer chemistry will be changing dramatically
over the next five to ten years because of the emphasis on 'green' products,"
explains Shulman. "Ingredients will have to be environmentally friendly,
and there will be an emphasis on making polymers biodegradable. Concern
about the effects of detergent products on the environment has brought
new activity to a relatively mature area of polymer science." Polymer
is an exciting field with new frontiers to be discovered.
Copyright 1994, 1997 American Chemical Society
Jim Mason Blending and Compounding
Today, there is almost no development of entirely new polymer materials.
However, blending and compounding existing polymers has become an important
part of a polymer chemist's work. "Compounding is both an art and
a science," says Jim Mason, a senior chemist in the polymers division
of Bayer Corporation. "Quite a bit of chemistry is involved. You
need to understand the reactions that go on in an extruder-the machine
used to compound." Compounding is often done to achieve certain properties
needed for a particular application.
One of Mason's recent projects was to develop a compounded polymeric
material to be used in the manufacture of lawn tractors. "Body panels
for these tractors are typically made of sheet metal," Mason explains.
"But many tractor manufacturers would like plastics instead of sheet
metal in the body panels. Existing plastics were not suited for this application,
so we tried blending different materials to come up with the right combination
of properties."
Mason worked directly with the tractor manufacturer to find out what
was needed. "One of the big requirements was high impact strength,"
he says. "Then if the tractor hit a tree, the material would not
shatter. We also needed to develop a material that had good weatherability
and could be mixed with pigment to get the right color." The chemist
and the customer collaborated to develop a material that is suited for
this application.
James Shepherd, Liquid-Crystal Polymers
In the 1970s and 1980s, some of the most lucrative polymer breakthroughs
occurred in the area of high-performance polymers. These materials were
expensive to produce but had new and desired qualities, such as high strength
and temperature resistance.
James Shepherd, research associate for polymer chemistry at Hoechst
Celanese, focuses on developing new high-performance polymers. One example
of successful high-performance polymer technology is liquid-crystal polymers
(LCPs). LCPs are polymers that are highly oriented; that means that when
they are heated above a certain temperature, the molecules align and flow
easily. The LCP can then be pushed through a spinnaret on a spinning machine
and made into a fiber, or can be injected into a small mold for an intricate
part used in the electronics business. One of the benefits of LCPs is
that they produce a material that is generally much stronger than those
produced from traditional plastics. One aspect that Shepherd stresses
is the importance of teamwork. "How to make the polymer is a team
decision. There are so many different aspects to bring together and different
talents required," he says. "It is not just the people in the
lab making the decision. We monitor the changing needs of our customers
and then determine how to produce the material with the properties they
want."
An illustration of this, says Shepherd, was when economics and environmental
issues required the molding industry to reuse the scrap material that
is a normal byproduct of molding plastic parts. "One problem with
doing this," he explains, "is that repeated processing cycles
can adversely affect the properties of the material." However, by
adjusting the chemistry and processing characteristics of a new LCP formulation,
chemists in Shepherd's lab developed a material that maintains its properties
after many processing cycles. In this way, basic researchers brought together
applications, chemists, and customers to find a mutually beneficial solution.
Terry St. Clair Polymers for Aerospace/NASA
Polymer development at NASA occupies a unique position in the field of
polymer chemistry. Terry St. Clair, head of the polymeric materials branch
at NASA Langley, explains that his work both serves NASA's polymer materials
needs and functions as an incentive for the rest of industry to make the
best polymer materials possible. "Our mission," he explains,
"is to make sure that the materials that aircraft companies need
are available. This, in some cases, forces industry to offer a more optimized
product than the one they might want to push.
"We do a lot of the same type of polymer work as is done in industry,
but in a broader and freer structure that is not confined by cost,"
he says. In some ways, this makes NASA a competitor with other polymer
makers, the difference being that NASA does not actually manufacture large
quantities of polymer materials. In some cases, St. Clair will work directly
with an aircraft company to develop the products it needs. "When
they have endorsed the material, we both go out into the market to try
to find someone to make it," he says.
Another aspect of his job is to develop polymers for highly focused
applications, such as the scientific instruments used in the space program.
Staff in St. Clair's lab were asked to make a polymer used in the window
of an X-ray telescope. "Only about five pounds of this material was
needed annually," he says. "We were in a position to develop
an exotic polymer where cost was not a factor. They would have been happy
to use platinum or gold if it would work."
[Photo courtesy DuPont Inc.]
Lycra spandex adds high-performance technology to this casual shirt. The
comfort and versatility of Lycra spandex throughout the garment make it
appropriate for a range of activities.
Jan Shulman, Detergent Polymers
Jan Shulman, a formulation chemist at Rohm and Haas, works with polymers
used in automatic dishwashing detergent products. "In this field,
polymers are key to making products work better," he says. One problem
Shulman deals with is the effects of sodium carbonate-or soda ash-in a
dishwashing detergent. "Soda ash is a main ingredient in many formulations,"
he says. "But when it reacts with water, it can form a chalky film
on glasses. When you add polymers to a formula, you can prevent this from
happening." Shulman says his lab facility includes dishwashers, plates,
and glasses. "We basically replicate what the consumer does at home
and conduct research to determine the most effective detergent formulation."
Shulman also works on formulation changes that are needed to address
concerns about the effects of traditional detergent ingredients on the
environment. "Most of this work involves reformulations around chlorine
and phosphates," he explains. Beginning in Europe in 1990, he says,
there was a move toward phosphate-free systems and an effort to replace
chlorine bleach with oxygen bleaches, such as those found in Clorox 2.
"Because this trend was making its way to the United States, it became
my job to work on reformulating products," he says. "When you
remove phosphates, you need to add a polymer to enhance performance. We
try to determine which polymers will fit the bill."
Kate Faron, Fibers
The general public is familiar with Lycra, or spandex, the stretch fabric
that goes into leggings, fitness wear, and bathing suits. Kate Faron,
a senior research chemist at DuPont, knows Lycra on the polymer level.
Part of Faron's job is to improve Lycra spandex for continued use in successful
fashion items. "When Lycra first replaced rubber thread, the market
grew in every segment," she explains. "We need to continue making
some changes to the fiber to keep growing. Most of the changes that we
make are incremental changes to existing products; but we still seek step-change
improvements, and there is always a lot of chemistry involved."
By changing the structure of the polymer or by using chemical additives,
Faron changes the properties of the spandex polymer. For example, how
it responds to light and heat can be modified chemically.
"Certain fabrics that do not already include Lycra might benefit
from elastic properties," she says. "We change the polymer to
meet the specifications of these new materials. It is macromolecular engineering,"
she says. "You need to know how to synthesize small molecules and
incorporate them into larger ones. You also have to understand the structure
you build and the properties you expect it to have."
John Droske, Polymer Education
"Approximately 50% of all chemists will work with polymers at some
time in their careers," says John Droske, professor of chemistry
at the University of Wisconsin-Stevens Point and director of the POLYED
National Information Center for Polymer Education. "Because polymer
science touches on many areas, it is important for chemists to be trained
in polymer science." The POLYED has been working with a National
Science Foundation grant to develop materials for polymer chemistry courses
at the undergraduate level.
Droske teaches courses on the synthesis and characterization of polymers
and the physical chemistry of polymers. He also conducts a polymer lab
course. The aspect of polymer science that Droske enjoys most is the challenge
of working with large molecules. "There is something unique about
studying polymers," he says. "Macromolecules have a greater
complexity than do small molecules. Over the years, our understanding
of these large molecules has increased so much that, although they remain
complex, we have tools that provide us with a better understanding of
their properties, enabling us to make connections between their structure
at the molecular level and their properties at the use level."
WORK DESCRIPTION
Polymer chemists are concerned with the study and synthesis of large,
complex molecules. They manipulate the molecular structure of a material
to develop functional characteristics in an end product by chemical processing
or through other processing conditions.
WORKING CONDITIONS
Polymer chemists spend most of their time in the lab; they also interact
with materials scientists or product manufacturing specialists in pilot
plant environments. Polymer chemists are increasingly expected to think
of the business opportunities for the products developed from their work.
Thus, chemists may work with marketing or sales representatives or directly
with customers.
PLACES OF EMPLOYMENT
Polymer chemists are employed in industry, government, and academia. However,
most jobs are in industry where products are made. Opportunities for polymer
chemists in industry exist in areas where adhesives, coatings, synthetic
rubber, synthetic fibers, agricultural chemicals, packaging, automotive,
aircraft, aerospace, and biomedical industries are made.
PERSONAL CHARACTERISTICS
A polymer chemist's work is interdisciplinary in nature. Individuals should
be able to communicate with others in a number of fields. Those who are
interested in materials and the end use of polymers as well as their synthesis
will be particularly well suited to the field. This is also be true for
individuals who like hands-on work as opposed to purely theoretical thinking.
EDUCATION AND TRAINING
Most people employed in polymer chemistry have a Ph.D. and were trained
as organic chemists. They stress the importance of a solid education in
the fundamentals of chemistry. However, they acknowledge the value of
the interdisciplinary degree available through programs in polymer science.
JOB OUTLOOK
Because polymer science is product-oriented, hiring can be expected to
follow the economy. Polymer chemists stress the need to remain as broad-based
and as flexible as possible for long-term employment security, but creative
and well-trained individuals should be able to find positions in this
field. Most major chemical companies have made deep cuts in their central
research divisions, and industry is still in a downsizing mode. The field
remains highly competitive, but some say they think these dynamics are
cyclical and that the job market will improve.
SALARY RANGE
Starting salaries for chemists in polymer science are in the high $40,000-per-year
range for those with a Ph.D., approximately $35,000-per-year for M.S.
degree holders, and in the mid $20,000-per-year range for someone with
a B.S. degree. The median salary for a Ph.D. polymer chemist in industry
is estimated to be approximately $75,000-per-year; $64,000-per-year for
chemists working in government labs; and $55,000-per-year for chemists
in academia.
FOR MORE INFORMATION
POLYED
National Information Center for Polymer Education
University of Wisconsin-Stevens Point
Department of Chemistry
Stevens Point, WI 54481
(715) 346-3703
Society of Plastics Engineers
P.O. Box 403
Brookfield, CT 06804-0403
(203) 775-0471
WHAT YOU CAN DO NOW
Only a few colleges and universities have programs in polymer science,
so a student's best access to experience in the field will be through
internships in industry or through summer employment at an institution
that has a polymers program.
American Chemical Society, Education Division, 1155 Sixteenth Street,
NW, Washington, DC 20036; (202) 452-2113.
Questions
or Comments? Email us at
cen-chemjobs.org © 2003 American Chemical Society
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