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Subject: Super Hard Steel coating - What Will It Give us?
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Apparently, the development of a new super-hard steel coating promises
many new great things. What will it give us in the military and
commercial fields?


---

http://www.eurekalert.org/pub_releases/2001-08/ine-iss080701.php


Public release date: 7-Aug-2001

Contact: Deborah Hill
dahill@inel.gov
208-526-4723
Idaho National E & E Laboratory 

INEEL's Super-Hard Steel one of this year's top 100 technological
achievements
Super Hard Steel forms a tough, low cost, wear and corrosion resistant
coating that outperforms traditional high-performance coatings.
Developed at the Department of Energy's Idaho National Engineering and
Environmental Laboratory, this coating offers a wealth of
possibilities for new industrial applications.
One of the hardest metallic materials known, Super Hard Steel has been
recognized as one of the 100 most significant technological
achievements for the year 2001 by R&D Magazine. Super Hard Steel can
be sprayed onto a wide variety of metal surfaces using conventionally
available thermal spray technologies, and surpasses the existing
commercial coatings in wear, corrosion and impact resistance.

Researchers create the Super Hard Steel coating by transforming steel
alloy into a non-crystalline metallic glass. "We essentially coach
mother nature to frustrate the atoms in the alloy, and capture a
snapshot in time when the atoms have a liquid structure in order to
form a very hard and strong solid," said INEEL materials scientist
Daniel Branagan. Because metallic glass has an extremely low density
of defects such as tiny cracks or holes, Super Hard Steel responds
differently to external stresses such as physical loads than metals
with a high density of defects. This property of metallic glass makes
the material both hard and tough-perfect for use as a impact resistant
coating.

Alternatively, for specific applications researchers can heat the
coating to create a stable structure made up of crystal grains from 2
to 75 nanometers in size, only slightly larger than a single atom.
"This approach is a much more robust route to forming nanoscale
crystalline structure when compared with other approaches that try to
maintain the nanoscale features during the production process," said
Branagan.

Once sprayed on, the Super Hard Steel coating cannot be removed-even
with a hammer and chisel. Because the material is sprayed on under
high-pressure conditions, the material remains in a compressed state
even after it cools, which makes it stronger. The coating was tested
using high velocity (170 mph), high intensity grit blasting for four
times longer than the normal testing standard, and showed no evidence
of cracking or wear.

Super Hard Steel has hardness properties among the highest ever
reported for any metallic structure or alloy-up to 16 giga Pascals. In
comparison to existing high performance coatings, Super Hard Steel is
significantly harder than electrolytic hard chrome and approaches the
best tungsten carbide. In an independent, standard abrasion test,
Super Hard Steel actually wore down the hardest commercially available
pin material, silicon nitride, which is used to develop wear scars on
hard coatings. The extreme hardness of Super Hard Steel in conjunction
with its metallic bonds gives the material abrasion wear resistance
properties that Branagan believes will significantly improve the
lifetime of coated machine parts. The unlubricated material also
exhibits a low coefficient of friction in the range of lubricated
steel, another property that can be exploited for a range of
applications.

The properties of Branagan's metal coatings are such an improvement
over current products and technologies, that he has had a hard time
convincing people to believe what they're seeing. "Industry just
doesn't believe our data at first," he said. In one instance, a
skeptical company president handed a coated sample to a technician for
testing while Branagan was giving his presentation. "I was a little
nervous," Branagan said, "but I just kept going with my presentation."
Not long later the technician returned and reported that the sample
had survived the testing completely unscathed. "The room went silent,"
he said. "Then I really had their attention."

Developed during several years of research funded by both INEEL
discretionary research funding and the Defense Advanced Research
Projects Agency, this technology has the potential for tremendous
impact to the manufacturing industry. "I'm proud of the award-winning
work done at the department's Idaho National Engineering and
Environmental Laboratory. This accomplishment demonstrates the value
of government-funded research to the Nation," Energy Secretary Spencer
Abraham said.

Branagan sees the possibilities for coatings like his to be nearly
endless because all areas of industry experience wear and corrosion
problems. The product is also extremely affordable because it is only
a steel which has exotic structures. It costs only a fraction of what
hard ceramics such as tungsten carbide. He feels that the biggest cost
savings will occur over the lifetime of a coated part since the
machine will simply last much longer, and require significantly less
maintenance. From the beginning, Branagan's goal was to develop a
coating that would have real-world applicability. "We purposely used
off-the shelf technology to apply the coatings with the idea of
increasing the ease of getting this technology out to industry,"
Branagan said.

Over the next year, Branagan will work with a range of industrial
partners to conduct proof-of-concept tests, putting his coating
through extensive erosion, corrosion, and fatigue testing. More than
15 companies are reviewing Super Hard Steel for licensing or testing,
in such applications as varied as self-sharpening knives and mining
rock crushers. Additionally, the technology will soon be applied to
key military devices for extensive testing in tough applications with
challenging environments.

Super Hard Steel represents one of the first fruits from of the
emerging field of nanoscale science. "What really spawned the
development of this technology was the development of a new material
in combination with sustained advances in the science of thermal
spray," Branagan said. "It's interesting to see how development in one
area of research spawns advancements in another."

The research team includes INEEL materials scientists Daniel Branagan,
Elizabeth Taylor and Joseph Burch, and thermal spray researchers James
Fincke, David Swank and DeLon C. Haggard. Also included is former
INEEL laboratory director Bart Krawetz, now retired from Lockheed
Martin Missile and Space Systems.

R&D Magazine has sponsored the international R&D 100 Awards program
since 1963. This is the 27th such award for the INEEL and the second
for Branagan and Fincke, who won awards in 1999 and 1997 respectively.
The research team from the Department of Energy's Idaho National
Engineering and Environmental Laboratory will receive its award at the
Museum of Science and Industry in Chicago in October 2001. For more
information about the awards program and this year's winners, access
the web site at http://www.rdmag.com.


###
The INEEL is a science-based applied engineering national laboratory
dedicated to supporting the DOE's missions in environment, energy,
science and national defense. The INEEL is jointly operated for the
DOE by Bechtel BWXT Idaho, LLC, and the Inland Northwest Research
Alliance.
Technical contact: Daniel J. Branagan, 208-526-4674, or
brandj@inel.gov

Media contact: Deborah Hill, 208-526-4723, or dahill@inel.gov; or Mary
Beckman, 208-526-0061, or beckmt@inel.gov.

Visit our web site at http://www.inel.gov
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