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1982
Monitoring Enviromental Pollution
The environmental
movement of the 1970s was sustained by many research projects at
NIST, which developed standards and methods for measuring all sorts
of pollutants in air, water, soil, and sediment. Many NIST innovations-such
as an instrument that characterizes microscopic particles in the
air and standards for measuring fuel economy and emissions-remain
in use today.
NIST also served
as an objective technical resource and trusted arbiter when asked
by the Environmental Protection Agency (EPA) to help resolve one
of the most contentious issues of the era-the extent of chemical
contamination of the Love Canal area of Niagara Falls, N.Y. The
EPA conducted an environmental monitoring program at Love Canal
and asked NIST to review the draft analysis for organic chemicals.
NIST experts
in organic analytical chemistry, quality assurance, and statistics
reviewed certain aspects (although not the conclusions) of the draft.
They found a number of significant deficiencies; among them, EPA's
study design did not permit a comparison of contamination levels
at Love Canal with those deemed hazardous or found in U.S. cities.
But the Institute also determined that the analytical techniques
were appropriate to the general goals of the study and represented
the best overall techniques for monitoring organic chemicals in
environmental samples. Ultimately, the EPA concluded that no significant
amounts of contamination were found except in the immediate vicinity
of the canal, in nearby storm sewers, and in the creeks near sewer
outfalls.
Although the
NIST report was critical of some aspects of the EPA study, which
was released in 1982, an EPA administrator called it "the most thorough,
extensive, state-of-the-art environmental study ever undertaken"
and described NIST participation as "essential for the successful
completion of the study."
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1984
Defining the Volt, Absolutely
Some scientists
predicted that such a feat would be impossible. Others tried it
and failed. But NIST succeeded in developing a standard for the
volt that is more accurate, more stable, and much easier to use
than its predecessors.
The NIST standard
is absolute in the sense that it is based directly on a single,
simple equation of physics and thus offers a major advantage over
previous standards. It is based on the “Josephson effect,”
observed when two superconducting materials are separated by a thin
insulating film and a current tunnels through the barrier (or junction).
When such a device is irradiated with microwave radiation of known
frequency, a voltage is induced across its terminals that is related
to the frequency and two well-known fundamental atomic constants.
The magnitude of the voltage can be calculated readily from the
known frequency and constants.
It was not
easy putting the Josephson effect to metrological use. A single
junction produces a maximum output of a few millivolts, much less
than the standard device then used by the Institute to represent
1 volt.
(For years, the legal volt was maintained on the basis of the “mean
electromotive force” of a bank of electrochemical cells, a
value that drifted over time and between labs.) Then in 1970, NIST
developed an instrument based on Josephson junctions that could
generate a signal of 2 to 10 millivolts and compared it to the U.S.
legal volt with acceptable accuracy.
The big breakthrough
came in 1984, when NIST demonstrated the first practical array of
Josephson junctions at the 1-volt level. (The photo above shows
the standard undergoing testing.) Two years later, a 10-volt standard
was developed. With almost 20,000 junctions, it was, for a time,
the largest practical superconducting circuit in the world. Today,
at least 40 national standards laboratories, military organizations,
and private companies worldwide rely on standards based on NIST-developed
technology to calibrate voltmeters. Products made with these instruments
range from compact disk players to missile guidance systems.
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1984
Discovering a New Material
When a peculiar
arrangement of metallic particles first appeared under an electron
microscope at NIST, scientists thought it was a mistake. It was
unlike any of the 230 crystal shapes described in reference books.
But the pattern turned out to be a true reflection of the structure
of a “quasicrystal”—an entirely new material.
The discovery
of quasicrystals by NIST guest researcher Dan Shechtman (one of
hundreds of guest researchers who collaborate with NIST scientists
and use the facilities every year) was reported in 1984 by a team
that included Institute scientist John Cahn, who subsequently developed
models that enhanced understanding of the crystallography of these
materials. The 1984 paper was cited 2,330 times in other publications
by 1998, evidence of its wide influence.
Although initially
skepticism was rampant, and alternate models of the structure were
proposed for several years, quasicrystals eventually rewrote the
rules of crystallography and spawned a flurry of activity in materials
science, physics, and mathematics. Cahn later won the National Medal
of Science, the nation’s highest scientific honor, for his
lifetime contributions to the fields of materials science, solid-state
physics, chemistry, and mathematics.
The breakthrough
was “pure serendipity,” in Cahn's words, an unexpected
boon of NIST research on the thermodynamics of rapidly solidified
alloys. The researchers intended to cool a molten metal so fast
that it would not crystallize in the usual manner. To their surprise,
the aluminum and manganese atoms formed orderly structures that,
unlike ordinary crystals, did not repeat at fixed intervals.
More than just
an academic research topic, quasicrystals have practical uses because
they are hard, lightweight, low friction, non-stick, non-scratch,
and inexpensive. By the late 1990s, they were being commercialized
as coatings for kitchen cookware and hardening agents for steel
medical instruments. Many other uses are expected.
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| ©
H. Mark Helfe |
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1989
Saving the Ozone Layer
The Earth is
better protected from the sun today thanks to NIST research and
data programs, which have helped to both define and solve the problem
of chemical damage to the protective ozone layer.
Fundamental
research by NIST in the 1970s underlined the damage caused by chlorofluorocarbons
(CFCs) from aerosol propellants and refrigerants. NIST and the National
Oceanic and Atmospheric Administration used laser spectroscopic
techniques developed at NIST to identify and measure critical chemical
reactions and then input the results into a computer model of the
upper atmosphere. Because of this research, damage to the ozone
layer from fluoro-carbons was estimated to be three times greater
than previously assumed.
With more than
50 years experience in providing industry with data on the physical
properties of refrigerants, the Institute responded to an international
agreement to phase out ozone-depleting compounds by launching a
major effort to identify and characterize alternatives to CFCs.
In 1989, NIST introduced REFPROP, a standard reference database
of the thermophysical properties of alternative refrigerants. The
Air Conditioning and Refrigeration Institute and the Electric Power
Research Institute adopted REFPROP as the source of critically evaluated
data for their alternative refrigerants evaluation program. The
database, which has saved industry millions of dollars, is a prime
example of how NIST and industry work together to successfully meet
needs for reliable technical data.
Today, CFCs
are being replaced by newer, less damaging refrigerants. REFPROP
has proven especially valuable in the evaluation of refrigerant
blends, such as those now used in some home air-conditioning systems
and heat pumps. NIST has distributed widely used software that models
important engineering aspects of the use of new refrigerant blends.
In addition, Institute refrigerant data were used to validate the
choice of an alternative refrigerant used in a wide variety of refrigeration
and air-conditioning systems, including those in newer cars.
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Date created:
11/6/00
Last updated: 11/15/00
Contact: inquries@nist.gov
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