 |
|
Smart memory foam made smarter
September 24, 2009Metallic foam less expensive to make, leading to more applications
Researchers from Northwestern University and Boise State University have figured out how to produce a less expensive shape-shifting "memory" foam, which could lead to more widespread applications of the material, such as in surgical positioning tools and valve mechanisms.
The alloy retains its new shape when the field is turned off but returns to its original shape if the field is rotated 90 degrees, demonstrating "magnetic shape-memory." The alloy can be activated millions of times, and it deforms reliably and reproducibly as a result. This property could be used to advantage in fast-operating actuators (mechanical devices for moving or controlling a mechanism or system) in inkjet printers, car engines and surgical tools.
To date, the magnetic shape-memory effect has occurred only in nickel-manganese-gallium single crystals, which are much more difficult and expensive to create than the more common polycrystals.
Now, Dunand, Müllner and their colleagues have created easily processable polycrystalline foams with shape-changing properties resembling those of the much more expensive single crystals. They did this by introducing small pores into the "nodes" of their original metallic foam, which, much like a sponge, consisted of struts connected by relatively large nodes. Adding a second level of porosity allowed for deformation and retention in the polycrystalline foam of some of the shape-memory properties.
The results are published online by the journal Nature Materials.
"One key aspect of this new 'smart' foam is that, together with a simple coil to produce a magnetic field, it creates a linear actuator of extreme simplicity -- and thus high reliability and miniaturization potential -- replacing a much more complex electro-mechanical system with many moving parts," Dunand said.
Potential applications range from replacing materials currently being used in sonar devices, precision actuators and magneto-mechanical sensors to enabling new devices in biomedicine and microrobotics.
"This was such a huge improvement that the foam was tested over and over again to make sure that no experimental mistakes were made," Müllner said. "Our new results may pave the way for magnetic shape-memory alloys for use in research labs and commercial applications."
Northwestern and Boise State have jointly filed a patent application.
Northwestern University
Metal Foam Has a Good Memory
In the world of commercial materials, lighter and cheaper is usually better, especially when those attributes are coupled with superior strength and special properties, such as a material's ability to remember its original shape after it's been deformed by a physical or magnetic force.
More Magnetic Shape-memory Current Events and Magnetic Shape-memory News Articles
|
Advances in Shape Memory Materials: Magnetic Shape Memory Alloys (Materials Science Forum) by V. A. Chernenko (Editor) This specialist book, the first of its kind, includes original and review articles which describe magnetic shape-memory alloys and the magnetic shape-memory effect. These topics are currently the object of world-wide research and development. In particular, the authors in the present book concentrated upon describing the phenomenological and microscopic mechanisms of the magnetic shape-memory effect, on the physical basis of the advanced properties of magnetic shape-memory alloys and on the structural aspects of martensitic transformations in both ferromagnetic and non-ferromagnetic shape-memory alloys. Several chapters are devoted to more general issues such as damping, the newly-discovered glassy martensite and modeling.The reader will also find copious information on technical... | |
 |
U.S.A. Magnetic Puzzle Map by Ata Boy Great magnetic tool for teaching geography. These magnetic states stick to the playboard to create the USA map. Each state magnet features landmarks, capitals and major cities and roadways. Click on the smaller image to view the playboard without the magnetic states. The magnetic map measures 16.5" x 10.75". Please Note: This set comes complete with interlocking state magnets, as shown. It is not designed for the tourist style magnets offered on our site. |
 |
World Magnetic Puzzle Map by Ata Boy Great magnetic tool for teaching geography. These magnetic countries stick to the playboard to create the World map. Each country magnet features landmarks, capitals and major cities and roadways. Click on the smaller image to view the playboard without the magnetic states. The magnetic map measures 16.5" x 10.75". Please Note: This set comes complete with interlocking state magnets, as shown. It is not designed for the tourist style magnets offered on our site. |
|
Magnetic Shape Memory Alloys (Materials Research Society Symposium Proceedings) by Materials Research Society (Mrs) (Author) | |
 |
Nanoscale Magnetic Materials and Applications by J. Ping Liu (Editor), Eric Fullerton (Editor), Oliver Gutfleisch (Editor), D.J. Sellmyer (Editor) Nanoscale Magnetic Materials and Applications covers exciting new developments in the field of advanced magnetic materials. Readers will find valuable reviews of the current experimental and theoretical work on novel magnetic structures, nanocomposite magnets, spintronic materials, domain structure and domain-wall motion, in addition to nanoparticles and patterned magnetic recording media. Cutting-edge applications in the field are described by leading experts from academic and industrial communities. These include new devices based on domain wall motion, magnetic sensors derived from both giant and tunneling magnetoresistance, thin film devices in micro-electromechanical systems, and nanoparticle applications in biomedicine. In addition to providing... |
 |
Piezoelectric-Based Vibration Control: From Macro to Micro/Nano Scale Systems by Nader Jalili (Author) “Piezoelectric-Based Vibration-control Systems: Applications in Micro/Nano Sensors and Actuators” covers: Fundamental concepts in smart (active) materials including piezoelectric and piezoceramics, magnetostrictive, shape-memory materials, and electro/magneto-rheological fluids; Physical principles and constitutive models of piezoelectric materials; Piezoelectric sensors and actuators; Fundamental concepts in mechanical vibration analysis and control with emphasis on distributed-parameters and vibration-control systems; and Recent advances in piezoelectric-based microelectromechanical and nanoelectromechanical systems design and implementation. |
 |
Smart Devices: Modeling of Material Systems: An International Workshop (AIP Conference Proceedings / Materials Physics and Applications) by Srinivasan Sivakumar (Author), Srinivasan Sivakumar (Editor), Vidyashankar Buravalla (Editor), A.R. Srinivasa (Editor) The SDMoMS workshop provided a forum for exchange of ideas between the smart material modeling community and the design community. The possibility of a common modeling framework was explored to come up with modeling tools and to enable designers with exercising their choice of materials from an array of existing smart materials, gather material property data, and compare and simulate these materials in a relatively simple manner before arriving at an optimal design. The workshop focused on materials such as shape memory materials, magnetic solids and fluids, polymers for smart applications and ferroelectrics. |
| © 2009 BrightSurf.com |