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PUBLIC RELEASE DATE:
18-Jan-2013

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Contact: Iqbal Pittalwala
iqbal@ucr.edu
951-827-6050
University of California - Riverside
@UCRiverside

UC Riverside nanotechnologists help launch new national center devoted to microelectronics

$28 million grant to fund 'Center for Spintronic Materials, Interfaces and Novel Architectures,' aimed at supporting US semiconductor industry

IMAGE: UC Riverside's Roland Kawakami (top), Ludwig Bartels (center) and Cengiz Ozkan are members of a new national research center focused on developing the next generation of microelectronics.

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RIVERSIDE, Calif. - Three University of California, Riverside scientists and engineers are members of a new national research center -- the Center for Spintronic Materials, Interfaces, and Novel Architectures (C-SPIN) -- focused on developing the next generation of microelectronics. Led by the University of Minnesota, C-SPIN is being supported by a five-year $28 million grant, about $3 million of which is allocated to UC Riverside.

The grant was awarded by the Semiconductor Research Corporation, a global research collaboration of private companies, universities and government agencies; and the Defense Advanced Research Projects Agency (DARPA).

C-SPIN at the University of Minnesota will bring together top researchers from across the nation, such as UCR's Roland Kawakami, Ludwig Bartels and Cengiz Ozkan, to develop technologies for spin-based computing and memory systems. Unlike today's computers, which function on the basis of electrical charges moving across wires, emerging spin-based computing systems will process and store information through spin, a fundamental property of electrons.

"Conventional silicon electronics is running out of steam in terms of improving its performance." said Kawakami, a professor of physics and astronomy. "It is known as the 'end of the roadmap' for silicon-based technologies. Silicon won't go away, but there are physical limits to how small silicon transistors can get before they stop working. Technology is now getting very close to this limit, so the semiconductor companies are looking for alternative methods for continued improvement in electronics."

Kawakami's research group will be working on the fabrication and testing of spintronic devices made from two-dimensional crystals, namely metal dichalcogenides (inorganic materials with unique electronic properties) and graphene. Bartels's and Ozkan's research groups will be working on the growth and characterization of two-dimensional metal dichalchogenides. Bartels, a professor of chemistry, Ozkan, a professor of mechanical engineering, and Kawakami are part of the Materials Science and Engineering Graduate Program at UCR.

C-SPIN's director Jian-Ping Wang, an electrical and computer engineering professor at the University of Minnesota, explained that the ability to scale semiconductor technology has led to the information revolution of the past half-century.

"However, today's semiconductor technology is reaching its fundamental limits in terms of density and power consumption," he said. "Spin-based logic and memory based on the hybridization of magnetic materials and semiconductors have the potential to create computers that are smaller, faster and more energy-efficient than conventional charge-based systems."

Spin-based computing has gained considerable interest recently due to advances in a number of areas. It can combine memory and logic at the device and circuit level, thereby leading to much faster operation for data-intensive applications. This is crucial in the information age and includes applications such as searching, sorting, and image recognition.

Especially important is the room temperature spin transport in graphene with high spin injection efficiency, first demonstrated by Kawakami's group. C-SPIN will help develop the graphene spintronic devices as well as explore new two-dimensional metal dichalcogenides, which are expected to allow for more facile spin manipulation.

"All the work on spin in two-dimensional crystals is at the cutting edge of science and engineering," Kawakami said.

Research at C-SPIN is expected to have an impact beyond the world of computer science and engineering resulting in advances in nanotechnology, materials science, physics, chemistry, circuit design, and many other fields. Headquartered at the University of Minnesota-Twin Cities, the center will fund research for 31 leading experts from 14 universities working in six scientific disciplines. C-SPIN will also fund research from more than 60 doctoral and post-doctoral students and host industry researchers-in-residence.

In addition to the University of Minnesota-Twin Cities and UCR, the 12 other universities involved are Carnegie Mellon University; Cornell University; Johns Hopkins University; Massachusetts Institute of Technology; Pennsylvania State University; Purdue University; University of Alabama; University of California, Santa Barbara; University of Iowa; University of Michigan; University of Nebraska; and University of Wisconsin-Madison.

Industry partners include Applied Materials, Global Foundries, IBM, Intel Corporation, Micron Technology, Raytheon, Texas Instruments and United Technologies.

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The University of California, Riverside (www.ucr.edu) is a doctoral research university, a living laboratory for groundbreaking exploration of issues critical to Inland Southern California, the state and communities around the world. Reflecting California's diverse culture, UCR's enrollment has exceeded 21,000 students. The campus will open a medical school in 2013 and has reached the heart of the Coachella Valley by way of the UCR Palm Desert Center. The campus has an annual statewide economic impact of more than $1 billion. A broadcast studio with fiber cable to the AT&T Hollywood hub is available for live or taped interviews. UCR also has ISDN for radio interviews. To learn more, call (951) UCR-NEWS.



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