|
.
. . Embraces life processes for obtaining
food
Agricultural chemistry focuses on chemical
compositions and changes involved in
the production, protection, and use
of crops and livestock. It is directed
toward control of processes by which
humans obtain food and fiber for themselves
and feed for their animals to increase
yields, improve quality, and reduce
costs. Agricultural chemists study the
causes and effects of biochemical reactions
related to plant and animal growth,
seek ways to control these reactions,
and develop chemical products that provide
help in controlling these reactions.
Chemical products developed to assist
in the production of food, feed, and
fiber include herbicides, fungicides,
insecticides, pesticides, plant growth
regulators, fertilizers, and animal
feed supplements.
.
. . Regulates safe use of chemicals
Every year, millions of pounds of agricultural
chemicals are used in herbicides, fungicides,
and insecticides that are applied to
crops in the United States. Part of
Julie Eble's job is to make sure these
products are safe for humans and for
the environment. Eble is a chemist and
environmental planning studies coordinator
for the agriculture products division
at DuPont. "These chemicals are
applied in huge quantities to commercial
crops. In a test field, we study air,
plants, soil, and water for the presence
of chemicals." A significant presence
of these chemicals or their metabolites-compounds
the chemicals break down into-may pose
a threat of toxicity.
Ed Johnson, a support scientist at the
U.S. Department of Agriculture (USDA),
does similar work, although he works
for the U.S. government rather than
industry. "I focus on the fate
of pesticides, finding out where they
go that we do not expect," he says.
He tests for these chemicals in the
atmosphere, surface water, and groundwater.
In some cases, the work that Eble and
Johnson do results in changes in the
way that some chemicals are used.
.
. . Offers a variety of opportunites
Eble and Johnson's work are just one
example of the work of agricultural
chemists . Some chemists develop molecules
used in herbicides or pesticides, while
some develop molecules that can be used
on crop fields in lower concentrations
than are traditional products. Many
are focused on other business-related
aspects of the field.
Some chemists are employed in the field
of agricultural biotechnology. Agricultural
biotechnology is currently focused on
three major areas: genetic engineering
of crops to be more herbicide tolerant
or less apt to be killed along with
the weeds during herbicide treatment;
genetic engineering of produce, such
as tomatoes or potatoes, to improve
taste and color and promote longer shelf
life; and the improvement of plants'
natural tolerance to certain pests.
An example of the latter is Calgene's
work on injecting the Bacillus thuringiensis
(Bt) protein into its proprietary cotton
varieties. This causes the plants to
produce a Bt toxin that kills Heliothis,
a principal cotton insect pest. Herbicides
engineered for crop tolerance are thought
to be safe and more environmentally
friendly.
. . . Is business-oriented
Keith Anderson, a Science Fellow in
the process development section of Monsanto
Agriculture Company, says, "Here,
we look at how to make the molecule
at a certain price rather than at biological
activity." Cost is probably the
biggest issue in his work. "In
the past 10 years, there has been a
major change in industrial research,"
he says. "We no longer have the
luxury of making products that do not
have a market. As researchers, we now
constantly have to ask the question,
'What is our work doing for the company?'"
Both Eble and Johnson say that while
the work is very team-based, there's
still autonomy in research as long as
the research ultimately has an application
that will benefit agriculture.
. . . Is interdisciplinary
"I work a lot with scientists in
other fields," Eble says, "including
agronomists, biologists, toxicologists,
and biochemists. We tell them the level
of a product in the field and they tell
us its impact on animals and plants."
Anderson says, "There is a wide
spectrum of research projects in this
field. Thus, it is important to be able
to work, or at least to be conversant,
in other fields. It is not good to have
tunnel vision; you need to make yourself
as well-rounded as possible."
Agricultural chemistry is not a distinct
discipline. It ties together genetics,
physiology, microbiology, entomology,
and other sciences that cross into agriculture
as chemical techniques, for example,
help evolve more productive plant and
animal strains; determine the kinds
and amounts of nutrients needed for
optimum growth of plants and animals;
and determine a soil's ability to provide
essential nutrients for the support
of crops or livestock. Every scientific
discipline that contributes to agricultural
progress depends in some way on chemistry.
Copyright 1994, 1997 American Chemical
Society
Work
Description
Research projects for agricultural chemists
cover many fields of inquiry including
the development of a molecule or chemical
compound that kills a pest or a weed,
the development of that molecule for
full-scale manufacturing, modifications
on the molecule so that it works for
longer periods of time or at lower dosages,
and testing for the impact and fate
of the chemical on the environment.
Working
Conditions
Agricultural chemists generally work
in a lab or a simulated environment
such as a test field or test waterway.
In testing for the presence and fate
of agricultural chemicals, analytical
chemistry methods are used. In development
work, agricultural chemists rely heavily
on their training in process chemistry
and basic organic chemistry.
Places
of Employment
Agricultural chemists are employed in
universities; government agencies, such
as the U.S. Department of Agriculture
and the U.S. Environmental Protection
Agency; and in industry. Some of the
large chemical companies count their
agricultural divisions as their most
lucrative businesses. The increase in
environmental regulations has created
opportunities in environmental chemistry
work within the agricultural chemicals
industry. However, the primary focus
for most of these companies is still
developing and selling agricultural
chemicals at the most competitive price.
Personal
Characteristics
Because agricultural chemicals potentially
come in contact with everything from
crops to weeds to plankton, soil, air,
animals, and humans, an agricultural
chemist must be able to think in an
interdisciplinary manner. Those students
with an interest in the environment
will likely be attracted to the high
degree of involvement with environmental
issues in this field. In addition, good
communications skills are a must as
team efforts are becoming the characteristic
work model in most labs.
Education
and Training
A high number of Ph.D. chemists work
in the agricultural chemicals field,
although an advanced degree is not a
prerequisite for promotion in a company.
A Ph.D., however, generally gets an
individual more complex and challenging
research assignments earlier in their
career. Agricultural chemists recommend
that students take courses in biology,
biochemistry, human toxicology, water
and soil chemistry, and geology. Knowledge
of computers and a course in research
ethics are also strongly suggested.
Scientists already in the field point
out that there are now many more degree
programs in environmental sciences now
than existed in the past. These, they
say, are another route into this field.
Job
Outlook
The agricultural chemicals business
is experiencing a time of transition,
which makes the job outlook less clear
than it has been in the past. Fourteen
years ago a boom in agricultural chemicals
opened up the job market, but those
within industry say departments are
now getting smaller, and jobs are more
competitive. Agricultural companies
are consolidating, and agricultural
chemists expect the business will soon
be dominated by a few firms. Once this
reorganization has happened, clearer
hiring patterns will begin to emerge.
Most of the growth in agricultural chemistry
is in biotechnology and bioengineering.
Salary
Range
The starting salary for a Ph.D. chemist
is in the low $50,000-per-year range.
B.S. and M.A. degree holders going into
industry can expect to start anywhere
from the mid $20,000 to mid $30,000
per year range, depending on the size
of the company for which they work.
Jobs in government laboratories traditionally
pay less. Chemists in government starting
at a GS-9 level can expect to earn $28,000
annually. At a GSI-11 level, salaries
are closer to $36,000-per-year.
For
More Information
For information on industries and companies
that produce agricultural chemicals:
National Crop Protection Association
1156 15th Street NW, Suite 400, Washington,
DC 20005
(202) 296-1585
For information on opportunities for
agricultural chemists in biotechnology:
Biotechnology Industry Organization
1625 K Street NW, Suite 1100, Washington,
DC 20006
(202) 857-0244
What
You Can Do Now
Chemists in the agriculture business
say that any advantage a student can
gain through internships or summer jobs
at a company will be extremely helpful
because the job market is so competitive.
Personal contacts are important in this
field and will give you an opportunity
to discover if this field is right for
you.
|
