 |
|
MIT: Nanoengineered concrete could cut CO2 emissions
January 30, 2007CAMBRIDGE, Mass.—While government leaders argue about the practicality of reducing world emissions of carbon dioxide, scientists and engineers are seeking ways to make it happen.
One group of engineers at MIT decided to focus its work on the nanostructure of concrete, the world's most widely used material. The production of cement, the primary component of concrete, accounts for 5 to 10 percent of the world's total carbon dioxide emissions; the process is an important contributor to global warming.
In the January issue of the Journal of the Mechanics and Physics of Solids, the team reports that the source of concrete's strength and durability lies in the organization of its nanoparticles. The discovery could one day lead to a major reduction in carbon dioxide emissions during manufacturing.
"If everything depends on the organizational structure of the nanoparticles that make up concrete, rather than on the material itself, we can conceivably replace it with a material that has concrete's other characteristics-strength, durability, mass availability and low cost-but does not release so much CO2 into the atmosphere during manufacture," said Franz-Josef Ulm, the Esther and Harold E. Edgerton Professor of Civil and Environmental Engineering.
The work also shows that the study of very common materials at the nano scale has great potential for improving materials in ways we might not have conceived. Ulm refers to this work as the "identification of the geogenomic code of materials, the blueprint of a material's nanomechanical behavior."
Cement is manufactured at the rate of 2.35 billion tons per year, enough to produce 1 cubic meter of concrete for every person in the world. If engineers can reduce carbon dioxide emissions in the world's cement manufacturing by even 10 percent, that would accomplish one-fifth of the Kyoto Protocol goal of a 5.2 percent reduction in total carbon dioxide emissions.
Ulm considers this a very real possibility.
He and Georgios Constantinides, a postdoctoral researcher in materials science and engineering, studied the behavior of the nanostructure of cement. They found that at the nano level, cement particles organize naturally into the most densely packed structure possible for spherical objects, which is similar to a pyramid-shaped pile of oranges.
Cement, the oldest engineered construction material, dating back to the Roman Empire, starts out as limestone and clay that are crushed to a powder and heated to a very high temperature (1500 degrees Celsius) in a kiln. At this high temperature, the mineral undergoes a transformation, storing energy in the powder. When the powder is mixed with water, the energy is released into chemical bonds to form the elementary building block of cement, calcium-silicate-hydrate (C-S-H). At the micro level, C-S-H acts as a glue to bind sand and gravel together to create concrete. Most of the carbon dioxide emissions in this manufacturing process result from heating the kiln to a temperature high enough to transfer energy into the powder.
Ulm and Constantinides gathered a wide range of cement pastes from around the world, and, using a novel nano-indentation technique, poked and prodded the hardened cement paste with a nano-sized needle. An atomic force microscope allowed them to see the nanostructure and judge the strength of each paste by measuring indentations created by the needle, a technique that had been used before on homogenous materials, but not on a heterogeneous material like cement.
To their surprise, they discovered that the C-S-H behavior in all of the different cement pastes consistently displays a unique nanosignature, which they call the material's genomic code. This indicates that the strength of cement paste, and thus of concrete, does not lie in the specific mineral, but in the organization of that mineral as packed nanoparticles.
The C-S-H particles (each about five nanometers, or billionths of a meter, in diameter) have only two packing densities, one for particles placed randomly, say in a box, and another for those stacked symmetrically in a pyramid shape (like a grocer's pile of fruit). These correspond exactly to the mathematically proved highest packing densities allowed by nature for spherical objects: 63 and 74 percent, respectively. In other words, the MIT research shows that materials pack similarly even at the nano scale.
"The construction industry relies heavily on empirical data, but the physics and structure of cement were not well understood," said Constantinides. "Now that the nano-indentation equipment is becoming more widely available-in the late 1990s, there were only four or five machines in the world and now there are five at MIT alone-we can go from studying the mechanics of structures to the mechanics of material at this very small scale."
If the researchers can find-or nanoengineer-a different mineral to use in cement paste, one that has the same packing density but does not require the high temperatures during production, they could conceivably cut world carbon dioxide emissions by up to 10 percent.
This aspect of the work is just beginning. Ulm estimates that it will take about five years, and says he's presently looking at magnesium as a possible replacement for the calcium in cement powder. "Magnesium is an earth metal, like calcium, but it is a waste material that people must pay to dispose of," he said.
He recently formed a research team with colleagues in physics, materials science and nuclear engineering to perform atomistic simulations, taking the work a step deeper into the structure of this ubiquitous material.
The research was funded in part by the Lafarge Group.
Massachusetts Institute of Technology
"If everything depends on the organizational structure of the nanoparticles that make up concrete, rather than on the material itself, we can conceivably replace it with a material that has concrete's other characteristics-strength, durability, mass availability and low cost-but does not release so much CO2 into the atmosphere during manufacture," said Franz-Josef Ulm, the Esther and Harold E. Edgerton Professor of Civil and Environmental Engineering.
The work also shows that the study of very common materials at the nano scale has great potential for improving materials in ways we might not have conceived. Ulm refers to this work as the "identification of the geogenomic code of materials, the blueprint of a material's nanomechanical behavior."
Cement is manufactured at the rate of 2.35 billion tons per year, enough to produce 1 cubic meter of concrete for every person in the world. If engineers can reduce carbon dioxide emissions in the world's cement manufacturing by even 10 percent, that would accomplish one-fifth of the Kyoto Protocol goal of a 5.2 percent reduction in total carbon dioxide emissions.
Ulm considers this a very real possibility.
He and Georgios Constantinides, a postdoctoral researcher in materials science and engineering, studied the behavior of the nanostructure of cement. They found that at the nano level, cement particles organize naturally into the most densely packed structure possible for spherical objects, which is similar to a pyramid-shaped pile of oranges.
Cement, the oldest engineered construction material, dating back to the Roman Empire, starts out as limestone and clay that are crushed to a powder and heated to a very high temperature (1500 degrees Celsius) in a kiln. At this high temperature, the mineral undergoes a transformation, storing energy in the powder. When the powder is mixed with water, the energy is released into chemical bonds to form the elementary building block of cement, calcium-silicate-hydrate (C-S-H). At the micro level, C-S-H acts as a glue to bind sand and gravel together to create concrete. Most of the carbon dioxide emissions in this manufacturing process result from heating the kiln to a temperature high enough to transfer energy into the powder.
Ulm and Constantinides gathered a wide range of cement pastes from around the world, and, using a novel nano-indentation technique, poked and prodded the hardened cement paste with a nano-sized needle. An atomic force microscope allowed them to see the nanostructure and judge the strength of each paste by measuring indentations created by the needle, a technique that had been used before on homogenous materials, but not on a heterogeneous material like cement.
To their surprise, they discovered that the C-S-H behavior in all of the different cement pastes consistently displays a unique nanosignature, which they call the material's genomic code. This indicates that the strength of cement paste, and thus of concrete, does not lie in the specific mineral, but in the organization of that mineral as packed nanoparticles.
The C-S-H particles (each about five nanometers, or billionths of a meter, in diameter) have only two packing densities, one for particles placed randomly, say in a box, and another for those stacked symmetrically in a pyramid shape (like a grocer's pile of fruit). These correspond exactly to the mathematically proved highest packing densities allowed by nature for spherical objects: 63 and 74 percent, respectively. In other words, the MIT research shows that materials pack similarly even at the nano scale.
"The construction industry relies heavily on empirical data, but the physics and structure of cement were not well understood," said Constantinides. "Now that the nano-indentation equipment is becoming more widely available-in the late 1990s, there were only four or five machines in the world and now there are five at MIT alone-we can go from studying the mechanics of structures to the mechanics of material at this very small scale."
If the researchers can find-or nanoengineer-a different mineral to use in cement paste, one that has the same packing density but does not require the high temperatures during production, they could conceivably cut world carbon dioxide emissions by up to 10 percent.
This aspect of the work is just beginning. Ulm estimates that it will take about five years, and says he's presently looking at magnesium as a possible replacement for the calcium in cement powder. "Magnesium is an earth metal, like calcium, but it is a waste material that people must pay to dispose of," he said.
He recently formed a research team with colleagues in physics, materials science and nuclear engineering to perform atomistic simulations, taking the work a step deeper into the structure of this ubiquitous material.
The research was funded in part by the Lafarge Group.
Massachusetts Institute of Technology
Cement Current Events and Cement News RSSHybrid composite for root canal treatment
Unrelenting toothache means a visit to the dentist is inevitable, and if the tooth decay is really bad root canal treatment is often the only option.
Super sticky barnacle glue cures like blood clots
Barnacles are a big problem for boats. Adhering to the undersides of vessels, carpets of the crustaceans can increase fuel consumption by as much as 25%.
'Green' research at Louisiana Tech results in new geopolymer concrete technology
Dr. Erez Allouche, assistant professor of civil engineering at Louisiana Tech University and associate director of the Trenchless Technology Center, is conducting innovative research on geopolymer concrete and providing ways to use a waste byproduct from coal fired power plants and help curb carbon dioxide emissions.
Lime mortars in conservation - traditional materials and craft for the Future
Plaster made from lime is environment-friendly, repairable and sustainable. Despite this, lime plaster on historic buildings has been replaced in modern times by plaster containing Portland cement - which has caused severe damage to historic buildings.
Global public health the focus of scientific conference
Counterfeit and adulterated food and drugs and advances in measurement science used to detect them emerged as key themes of the Annual Scientific Meeting (ASM) hosted by the U.S. Pharmacopeial (USP) Convention.
Cement's basic molecular structure finally decoded
In the 2,000 or so years since the Roman Empire employed a naturally occurring form of cement to build a vast system of concrete aqueducts and other large edifices, researchers have analyzed the molecular structure of natural materials and created entirely new building materials such as steel, which has a well-documented crystalline structure at the atomic scale.
Vet says owners should exercise with their dogs based on specific needs to prevent obesity
People and their dogs both need physical activity to fight obesity, and there are many exercises that owner and pet can do together that can improve their health and their relationship, according to a Kansas State University expert.
New expensive back procedure exposed as ineffective
A world-first study involving Monash University and the Cabrini Research Institute in Melbourne has revealed the injection of bone cement into broken vertebrae is not an effective treatment for patients suffering painful osteoporotic fractures.
University of Minnesota research leads to new technology to protect human health
Larry Wackett and Michael Sadowsky, members of the University of Minnesota's BioTechnology Institute, developed an enzyme that is used in Bioo Scientific's new MaxDiscovery™ Melamine Test kit, which simplifies the detection of melamine contamination in food.
Alzheimer's disease drug treats traumatic brain injury, report GUMC researchers
The destructive cellular pathways activated in Alzheimer's disease are also triggered following traumatic brain injury, say researchers from Georgetown University Medical Center (GUMC).
More Cement Current Events and Cement News Articles
 |
Hitachi 725397 4-Inch 6 TPI Jig Saw Blades For Fiber Cement Siding - 3 Pack by Hitachi Fast Coarse Cutting in Abrasive Materials; FRP 1/4" to 3/4"; Cement Bonded Particle Board 1/4" to 2-3/8"; Fiber Cement (HardiBoard) |
 |
Cement (European Classics) by Fyodor Vasilievich Gladkov (Author), A.S. Arthur (Translator), C. Ashleigh (Translator) |
 |
Hitachi 18008 HardiBlade 7-1/4-Inch 4-Tooth PCD Fiber Cement Saw Blade with 5/8-Inch and Diamond Knockout Arbor by Hitachi Thin kerf saw blades for circular saws. Flat top .063" plate, .087" kerf, 12 degree hook angle. |
 |
PacTool International SS404 SteelHead Fiber Cement Cutting Shear by Pacific International The PacTool SS404 Fiber-Cement Shear cuts fiber-cement siding quickly, safely, and economically. Featuring reversible blades that are machined from solid steel, this versatile tool provides smooth, fast operation you can rely on. Most important, the SS404 won't produce airborne silica dust, so you can count on your jobsite being as healthy as can be.
|
 |
Cement Starring: Chris Penn, Jeffrey Wright, Anthony DeSando, Sherilyn Fenn, Henry Czerny Directed By: Adrian Pasdar Take a walk on the seamy side of town where you cant tell the difference between the bad cops and the crooks. Bob holt a corrupt detective knee-deep in kickbacks has an uneasy partnership with a drug-addicted cop and an even shakier alliance with a notorious mob syndicate. Studio: Lions Gate Home Ent. Release Date: 02/06/2007 Starring: Chris Penn Jeffrey Wright Run time: 100 minutes Rating: R |
 |
Cement Chemistry, second edition by H. F. W., Taylor (Author) H F W Taylor was for many years Professor of Inorganic Chemistry at he University of Aberdeen, Scotland. Since 1948, his main research interest has been the chemistry of cement. His early work laid the foundations of our understanding of the structure at the nanometre level of C-S-H, the principal product formed when cement is mixed with water, and the one mainly reponsible for its hardening. Subsequent studies took him into many additional aspects of the chemistry and materials science of cement and concrete. His work has been recognized by Fellowships and by other honours and awards from many scientific societies in the UK, USA and elsewhere. This second edition of Cement chemistry addresses the chemistry and materials science of the principal silicate and aluminate cements used in... |
 |
Hitachi 18108 10-Inch 6 Tooth Fiber Cement Cutting Blade with 5/8-Inch Arbor by Hitachi Thin kerf saw blades for circular saws. Alternate top bevel, .063" plate, .087" kerf, 12 degree hook angle. |
 |
Man with the Action Hair by Cement |
 |
Dap 14086 Box Quick Plug Hydraulic Cement 5-Pound by Dap Quick Plug, 5 LB, Hydraulic Cement, High Performance Patching Compound Formulated To Stop Running Water Through Deep Cracks, Holes & Imperfections In Concrete Surfaces, It Creates A Watertight Seal In 3 - 5 Minutes, Works Both Above & Below Ground Level. |
 |
Lea's Chemistry of Cement and Concrete, Fourth Edition by Peter Hewlett (Author) Lea's Chemistry of Cement and Concrete deals with the chemical and physical properties of cements and concretes and their relation to the practical problems that arise in manufacture and use. As such it is addressed not only to the chemist and those concerned with the science and technology of silicate materials, but also to those interested in the use of concrete in building and civil engineering construction. Much attention is given to the suitability of materials, to the conditions under which concrete can excel and those where it may deteriorate and to the precautionary or remedial measures that can be adopted. First published in 1935, this is the fourth edition and the first to appear since the death of Sir Frederick Lea, the original author. Over the life of the first three... |
| © 2009 BrightSurf.com |