text-only page produced automatically by LIFT Text Transcoder Skip all navigation and go to page contentSkip top navigation and go to directorate navigationSkip top navigation and go to page navigation
National Science Foundation
News
design element
News
News From the Field
For the News Media
Special Reports
Research Overviews
NSF-Wide Investments
Speeches & Lectures
NSF Current Newsletter
Multimedia Gallery
News Archive
News by Research Area
Arctic & Antarctic
Astronomy & Space
Biology
Chemistry & Materials
Computing
Earth & Environment
Education
Engineering
Mathematics
Nanoscience
People & Society
Physics
 

Email this pagePrint this page


New NSF Engineering Research Center to Create Chip-scale Electromagnetic Devices Enabled by Nanosystem Breakthrough

Images of a magnetic field turned on and off.

TANMS researchers have used an electric field to turn a magnetic field on (left) and off (right).
Credit and Larger Version

September 5, 2012

The National Science Foundation (NSF) announced today an award to the University of California Los Angeles and its partners to establish a new NSF Engineering Research Center (ERC) focused on nanoscale multiferroic devices that offer unprecedented capabilities to electromagnetic components. 

The ERC, one in a cohort of three with a nanosystems focus, will pursue interdisciplinary research and education to address questions important to both nanotechnology and multiferroic-based electronics and to meet critical industry needs through innovation. NSF will invest $18.5 million in the Center over the next five years.

The NSF Nanosystems Engineering Research Center (NERC) for Translational Applications of Nanoscale Multiferroic Systems (TANMS) intends to lead the integration of newly discovered large-effect multiferroic materials into electromagnetic devices, thereby enabling chip-scale generation of magnetic fields through the simple application of a voltage. Large magnetic effects are achieved in multiferroic materials by the nanoscale design of thin-film structures, where each layer is mechanically responsive to the application of either an electric field or a magnetic field -- a combination that previously was difficult to achieve. These materials recently emerged following breakthroughs in understanding magnetic effects on the nanoscale, the development of models that coupled nanoscale effects into macroscopic component simulations, and the subsequent mastery of nanoscale manipulation to make the designer materials.  

While electromagnetic devices have long been important in many communications and aerospace systems, they were difficult to miniaturize into chip-scale components, because the only way to create the magnetic component of the electromagnetic field was by setting up a current within the device. Unfortunately, the methods for current generation led to clumsy architectures that resisted scaling down to chip-size and were notorious power "hogs" that produced excessive heating. As a consequence, electromagnetic devices have not benefitted from the integrated circuit revolution that, driven by Moore's law, has led to smarter and faster electronic processors as the size of digital devices decreased. The discovery of multiferroic materials and their future integration into devices will enable electromagnetic devices to undergo a similar size transformation.

Recognizing this opportunity, this ERC aims to develop new modeling capabilities that will lead to optimized chip-scale designs for the classic electromagnetic applications in memory systems, antenna systems, and nanomotor systems. In addition, the TANMS researchers will continue to develop designer multiferroic materials and explore new application paradigms. To facilitate rapid translation of Center technology, the ERC researchers will collaborate closely with their industry partners. 

The lead institution for TANMS is the University of California-Los Angeles (UCLA), which will partner extensively with California State University-Northridge, Cornell University, and the University of California-Berkeley. Researchers at the Edgenossische Technische Hochschule (ETH) in Zurich, Switzerland, will contribute additional expertise while providing international opportunities for TANMS student education. 

Collaboration with more than 20 non-academic partners -- including small and large companies (particularly from aerospace, electronic components, and medical technology sectors), regional innovation organizations, and national laboratories -- will spur innovation and provide university students with first-hand experience in industrial manufacturing and entrepreneurship. The Center will also interact closely with complementary research centers and organizations specializing in technology transfer to stimulate innovation based on its research.

Since 1985, the ERC program has fostered extensive collaborations to create technological breakthroughs for new products and services and to prepare U.S. engineering graduates for successful participation in the global economy. The three centers launched this year, as part of the third generation of NSF ERCs (Gen-3 ERCs), place increased emphasis on innovation and entrepreneurship, partnerships with small research firms in translational research, education of an innovative engineering workforce, and international collaboration and cultural exchange.

The Nanosystems ERCs (NERCs) are expected to create transformational science and engineering platforms for the respective fields of nanoscale research, education, and innovation. As appropriate to its particular areas of research, each NERC will include the societal and environmental implications of the nano-enabled scientific and technological breakthroughs. The new centers are part of the National Nanotechnology Initiative (NNI), which provides a conceptual framework and additional collaborative opportunities, and they are strategically designed to build on more than a decade's worth of investment and discoveries in fundamental nanoscale science and engineering.

"This Center will bring together critical expertise in physics, materials science, and engineering to enable the integration of electromagnetic devices into chip-scale formats," said Lynn Preston, the leader of the ERC Program, "and we anticipate that, with these advances, multiferroic technologies will exhibit rapid growth."

-Cecile J. Gonzalez, NSF, cjgonzal@nsf.gov-

  

Media Contacts
Joshua A. Chamot, NSF, (703) 292-7730, jchamot@nsf.gov
Matthew Chin, University of California Los Angeles, (310) 206-0680, mchin@support.ucla.edu

NSF Program Contacts
Lynn Preston, NSF, (703) 292-5358, lpreston@nsf.gov
Deborah Jackson, NSF, (703) 292-7499, djackson@nsf.gov

Principal Investigator
Greg Carman, University of California Los Angeles, (310) 825-6030, carman@seas.ucla.edu

Related Websites
NSF ERC website: http://www.erc-assoc.org/   
National Nanotechnology Initiative (NNI):  http://nano.gov/ 
NNI at NSF:  http://www.nsf.gov/nano

The National Science Foundation (NSF) is an independent federal agency that supports fundamental research and education across all fields of science and engineering. In fiscal year (FY) 2014, its budget is $7.2 billion. NSF funds reach all 50 states through grants to nearly 2,000 colleges, universities and other institutions. Each year, NSF receives about 50,000 competitive requests for funding, and makes about 11,500 new funding awards. NSF also awards about $593 million in professional and service contracts yearly.

 Get News Updates by Email 

Useful NSF Web Sites:
NSF Home Page: http://www.nsf.gov
NSF News: http://www.nsf.gov/news/
For the News Media: http://www.nsf.gov/news/newsroom.jsp
Science and Engineering Statistics: http://www.nsf.gov/statistics/
Awards Searches: http://www.nsf.gov/awardsearch/

 

Image of a Nickel ring on a piezoelectric substrate.
A Nickel ring on a piezoelectric substrate may be used in the fabrication of nanoscale motors.
Credit and Larger Version



Email this pagePrint this page
Back to Top of page