From University of Michigan : “Harnessing the hum of fluorescent lights for more efficient computing”

U Michigan bloc

From University of Michigan

May 12, 2021

Contacts:
Gabe Cherry
gcherry@umich.edu,

Nicole Casal Moore
ncmoore@umich.edu

1
The property that makes fluorescent lights buzz could power a new generation of more efficient computing devices that store data with magnetic fields, rather than electricity.

A team led by University of Michigan researchers has developed a material that’s at least twice as “magnetostrictive” and far less costly than other materials in its class. In addition to computing, it could also lead to better magnetic sensors for medical and security devices.

Magnetostriction, which causes the buzz of fluorescent lights and electrical transformers, occurs when a material’s shape and magnetic field are linked—that is, a change in shape causes a change in magnetic field. The property could be key to a new generation of computing devices called magnetoelectrics.

Magnetoelectric chips could make everything from massive data centers to cell phones far more energy efficient, slashing the electricity requirements of the world’s computing infrastructure.

Made of a combination of iron and gallium, the material is detailed in a paper published May 12 in Nature Communications. The team is led by U-M materials science and engineering professor John Heron and includes researchers from Intel; Cornell University (US); University of California-Berkeley (US); University of Wisconsin (US); Purdue University (US) and elsewhere.

Magnetoelectric devices use magnetic fields instead of electricity to store the digital ones and zeros of binary data. Tiny pulses of electricity cause them to expand or contract slightly, flipping their magnetic field from positive to negative or vice versa. Because they don’t require a steady stream of electricity, as today’s chips do, they use a fraction of the energy.

“A key to making magnetoelectric devices work is finding materials whose electrical and magnetic properties are linked.” Heron said. “And more magnetostriction means that a chip can do the same job with less energy.”

Cheaper magnetoelectric devices with a tenfold improvement

Most of today’s magnetostrictive materials use rare-earth elements, which are too scarce and costly to be used in the quantities needed for computing devices. But Heron’s team has found a way to coax high levels of magnetostriction from inexpensive iron and gallium.

Ordinarily, explains Heron, the magnetostriction of iron-gallium alloy increases as more gallium is added. But those increases level off and eventually begin to fall as the higher amounts of gallium begin to form an ordered atomic structure.

So the research team used a process called low-temperature molecular-beam epitaxy to essentially freeze atoms in place, preventing them from forming an ordered structure as more gallium was added. This way, Heron and his team were able to double the amount of gallium in the material, netting a tenfold increase in magnetostriction compared to unmodified iron-gallium alloys.

“Low-temperature molecular-beam epitaxy is an extremely useful technique—it’s a little bit like spray painting with individual atoms,” Heron said. “And ‘spray painting’ the material onto a surface that deforms slightly when a voltage is applied also made it easy to test its magnetostrictive properties.”

Researchers are working with Intel’s MESO program

The magnetoelectric devices made in the study are several microns in size—large by computing standards. But the researchers are working with Intel to find ways to shrink them to a more useful size that will be compatible with the company’s magnetoelectric spin-orbit device (or MESO) program, one goal of which is to push magnetoelectric devices into the mainstream.

“Intel is great at scaling things and at the nuts and bolts of making a technology actually work at the super-small scale of a computer chip,” Heron said. “They’re very invested in this project and we’re meeting with them regularly to get feedback and ideas on how to ramp up this technology to make it useful in the computer chips that they call MESO.”

While a device that uses the material is likely decades away, Heron’s lab has filed for patent protection through the U-M Office of Technology Transfer.

The research is supported by IMRA America and the National Science Foundation (grant numbers NNCI-1542081, EEC-1160504 DMR-1719875 and DMR-1539918).

Other researchers on the paper include U-M associate professor of materials science and engineering Emmanouil Kioupakis; U-M assistant professor of materials science and engineering Robert Hovden; and U-M graduate student research assistants Peter Meisenheimer and Suk Hyun Sung.

See the full article here .


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The University of Michigan (U-M, UM, UMich, or U of M), frequently referred to simply as Michigan, is a public research university located in Ann Arbor, Michigan, United States. Originally, founded in 1817 in Detroit as the Catholepistemiad, or University of Michigania, 20 years before the Michigan Territory officially became a state, the University of Michigan is the state’s oldest university. The university moved to Ann Arbor in 1837 onto 40 acres (16 ha) of what is now known as Central Campus. Since its establishment in Ann Arbor, the university campus has expanded to include more than 584 major buildings with a combined area of more than 34 million gross square feet (781 acres or 3.16 km²), and has two satellite campuses located in Flint and Dearborn. The University was one of the founding members of the Association of American Universities (US).

Considered one of the foremost research universities in the United States, the university has very high research activity and its comprehensive graduate program offers doctoral degrees in the humanities, social sciences, and STEM fields (Science, Technology, Engineering and Mathematics) as well as professional degrees in business, medicine, law, pharmacy, nursing, social work and dentistry. Michigan’s body of living alumni (as of 2012) comprises more than 500,000. Besides academic life, Michigan’s athletic teams compete in Division I of the NCAA and are collectively known as the Wolverines. They are members of the Big Ten Conference.