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Topic Name: How cement and concrete actually work
Category: STRUCTURAL
Research persons: A.J. Allen, J.J. Thomas and H.M. Jennings
Location: NIST-Boulder, MS 104.00, 325 Broadway, Boulder, Colo. 80305-3328, United States
Details
Using
a brace of the most modern tools of materials research, a team from the National
Institute of Standards and Technology (NIST) and Northwestern University has
shed new light on one of mankind’s older construction materials—cement. Their
refinements to our understanding of how cement and concrete actually work,
reported this week in Nature Materials,* ultimately may make possible
improvements in the formulation and use of cement that could save hundreds of
millions of dollars in annual maintenance and repair costs for concrete
structures and the country’s infrastructure.
Cement may be the world’s most
widely used manufactured material—more than 11 billion metric tons are consumed
each year—but it also is one of the more complex. And while it was known to the
Romans, who used it to good effect in the Colosseum and Pantheon, questions
still remain as to just how it works, in particular how it is
structured at the nano- and microscale, and how this structure affects its
performance.
Cement is something of a paradox.
It requires just the right amount of water to form properly—technically it’s
held together by a gel, a complex network of nanoparticles called calcium
silicate hydrate (C-S-H) that binds a significant amount of water within its
structure. But once the cement has set, the C-S-H structure retains a tough,
unchanging integrity for centuries, even in contact with water. To date,
attempts to pinpoint the amounts and different roles of water within the C-S-H
in cement paste have required taking the water out, either by drying or chemical
methods. The NIST/Northwestern researchers instead combined structural data from
small-angle neutron scattering experiments at the NIST Center for Neutron
Research and from an ultrasmall-angle X-ray scattering instrument built by NIST
at the Advanced Photon Source at Argonne National Laboratory. Their experiments
are the first to classify water by its location in the cured cement.
As a result, the researchers were
able to distinguish—and measure—the difference between water physically bound
within the internal structure of the solid C-S-H nanoparticles and adsorbed or
liquid water between the nanoparticles. They also measured a nanoscale calcium
hydroxide structure that co-exists with the C-S-H gel. The new data, which imply
significantly different values for the formula and density of the C-S-H gel than
previously supposed, have implications for defining the chemically active
surface area within cement, and for predicting concrete properties. They also
may lead to a better understanding of the contribution of the nanoscale
structure of cement to its durability, and how to improve it.
In picture:
Schematic drawing of nanoscale
calcium silicate hydrate (C-S-H) particles in cement showing the multiple roles
played by water as defined in the NIST/Northwestern experiments. Solid red areas
are calcium silicate, pebbled areas in between show the water physically bound
between the layers to form solid C-S-H. Dark blue halos around the C-S-H
particles are water adsorbed on the surface; pale blue areas represent liquid
water caught in nanopores
About Researcher:
A. J. Allen
Ceramics Division, NIST,
Gaithersburg, MD 20899, USA
Jeffrey J. Thomas
Research Associate Professor
Department of Civil and Environmental Engineering
A220 Technological Institute
2145 Sheridan Rd. Evanston, IL 60208-3109
jthomas@northwestern.edu
phone: (847) 491-4997
H.M. Jennings
Funded:
NIST funds
industrial and academic research in a variety of ways. Our Advanced Technology
Program co-funds high-risk, high-payoff projects with industry. The Small
Business Innovation Research Program funds R&D proposals from small businesses.
We also offer other grants to encourage work in specific fields: precision
measurement, fire research, and materials science.
Grants/awards supporting research at industry, academic, and other institutions
are available on a competitive basis through several different Institute
offices. For general information on NIST grants programs, contact
Joyce Brigham, (301) 975-6329
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