Forum for Science, Industry and Business

Sponsored by:     3M 
Search our Site:

 

New quantum materials could take computing devices beyond the semiconductor era

04.12.2018

Mutliferroics are promising candidates for new type of memory and logic circuits

Researchers from Intel Corp. and the University of California, Berkeley, are looking beyond current transistor technology and preparing the way for a new type of memory and logic circuit that could someday be in every computer on the planet.


MESO devices, based on magneto-electric and spin-orbit materials, could someday replace the ubiquitous semiconductor transistor, today represented by CMOS. MESO uses up-and-down magnetic spin states in a multiferroic material to store binary information and conduct logic operations.

Credit: Intel graphic


Single crystals of the multiferroic material bismuth-iron-oxide. The bismuth atoms (blue) form a cubic lattice with oxygen atoms (yellow) at each face of the cube and an iron atom (gray) near the center. The somewhat off-center iron interacts with the oxygen to form an electric dipole (P), which is coupled to the magnetic spins of the atoms (M) so that flipping the dipole with an electric field (E) also flips the magnetic moment. The collective magnetic spins of the atoms in the material encode the binary bits 0 and 1, and allow for information storage and logic operations.

Credit: Ramamoorthy Ramesh lab, UC Berkeley

In a paper appearing online Dec. 3 in advance of publication in the journal Nature, the researchers propose a way to turn relatively new types of materials, multiferroics and topological materials, into logic and memory devices that will be 10 to 100 times more energy-efficient than foreseeable improvements to current microprocessors, which are based on CMOS (complementary metal-oxide-semiconductor).

The magneto-electric spin-orbit or MESO devices will also pack five times more logic operations into the same space than CMOS, continuing the trend toward more computations per unit area, a central tenet of Moore's Law.

The new devices will boost technologies that require intense computing power with low energy use, specifically highly automated, self-driving cars and drones, both of which require ever increasing numbers of computer operations per second.

"As CMOS develops into its maturity, we will basically have very powerful technology options that see us through. In some ways, this could continue computing improvements for another whole generation of people," said lead author Sasikanth Manipatruni, who leads hardware development for the MESO project at Intel's Components Research group in Hillsboro, Oregon. MESO was invented by Intel scientists, and Manipatruni designed the first MESO device.

Transistor technology, invented 70 years ago, is used today in everything from cellphones and appliances to cars and supercomputers. Transistors shuffle electrons around inside a semiconductor and store them as binary bits 0 and 1.

In the new MESO devices, the binary bits are the up-and-down magnetic spin states in a multiferroic, a material first created in 2001 by Ramamoorthy Ramesh, a UC Berkeley professor of materials science and engineering and of physics and a senior author of the paper.

"The discovery was that there are materials where you can apply a voltage and change the magnetic order of the multiferroic," said Ramesh, who is also a faculty scientist at Lawrence Berkeley National Laboratory. "But to me, 'What would we do with these multiferroics?' was always a big question. MESO bridges that gap and provides one pathway for computing to evolve"

In the Nature paper, the researchers report that they have reduced the voltage needed for multiferroic magneto-electric switching from 3 volts to 500 millivolts, and predict that it should be possible to reduce this to 100 millivolts: one-fifth to one-tenth that required by CMOS transistors in use today. Lower voltage means lower energy use: the total energy to switch a bit from 1 to 0 would be one-tenth to one-thirtieth of the energy required by CMOS.

"A number of critical techniques need to be developed to allow these new types of computing devices and architectures," said Manipatruni, who combined the functions of magneto-electrics and spin-orbit materials to propose MESO. "We are trying to trigger a wave of innovation in industry and academia on what the next transistor-like option should look like."

Internet of things and AI

The need for more energy-efficient computers is urgent. The Department of Energy projects that, with the computer chip industry expected to expand to several trillion dollars in the next few decades, energy use by computers could skyrocket from 3 percent of all U.S. energy consumption today to 20 percent, nearly as much as today's transportation sector.

Without more energy-efficient transistors, the incorporation of computers into everything - the so-called internet of things - would be hampered. And without new science and technology, Ramesh said, America's lead in making computer chips could be upstaged by semiconductor manufacturers in other countries.

"Because of machine learning, artificial intelligence and IOT, the future home, the future car, the future manufacturing capability is going to look very different," said Ramesh, who until recently was the associate director for Energy Technologies at Berkeley Lab. "If we use existing technologies and make no more discoveries, the energy consumption is going to be large. We need new science-based breakthroughs."

Paper co-author Ian Young, a UC Berkeley Ph.D., started a group at Intel eight years ago, along with Manipatruni and Dmitri Nikonov, to investigate alternatives to transistors, and five years ago they began focusing on multiferroics and spin-orbit materials, so-called "topological" materials with unique quantum properties.

"Our analysis brought us to this type of material, magneto-electrics, and all roads led to Ramesh," said Manipatruni.

Multiferroics and spin-orbit materials

Multiferroics are materials whose atoms exhibit more than one "collective state." In ferromagnets, for example, the magnetic moments of all the iron atoms in the material are aligned to generate a permanent magnet. In ferroelectric materials, on the other hand, the positive and negative charges of atoms are offset, creating electric dipoles that align throughout the material and create a permanent electric moment.

MESO is based on a multiferroic material consisting of bismuth, iron and oxygen (BiFeO3) that is both magnetic and ferroelectric. Its key advantage, Ramesh said, is that these two states - magnetic and ferroelectric - are linked or coupled, so that changing one affects the other. By manipulating the electric field, you can change the magnetic state, which is critical to MESO.

The key breakthrough came with the rapid development of topological materials with spin-orbit effect, which allow for the state of the multiferroic to be read out efficiently. In MESO devices, an electric field alters or flips the dipole electric field throughout the material, which alters or flips the electron spins that generate the magnetic field. This capability comes from spin-orbit coupling, a quantum effect in materials, which produces a current determined by electron spin direction.

In another paper that appeared earlier this month in Science Advances, UC Berkeley and Intel experimentally demonstrated voltage-controlled magnetic switching using the magneto-electric material bismuth-iron-oxide (BiFeO3), a key requirement for MESO.

"We are looking for revolutionary and not evolutionary approaches for computing in the beyond-CMOS era," Young said. "MESO is built around low-voltage interconnects and low-voltage magneto-electrics, and brings innovation in quantum materials to computing."

###

Other co-authors of the Nature paper are Chia-Ching Lin, Tanay Gosavi and Huichu Liu of Intel and Bhagwati Prasad, Yen-Lin Huang and Everton Bonturim of UC Berkeley. The work was supported by Intel.

Media Contact

Robert Sanders
rlsanders@berkeley.edu
510-643-6998

 @UCBerkeleyNews

http://www.berkeley.edu 

Robert Sanders | EurekAlert!

More articles from Information Technology:

nachricht A new way to see stress -- using supercomputers
03.12.2018 | University of Texas at Austin, Texas Advanced Computing Center

nachricht Tablet computers for the visually impaired
03.12.2018 | Albert-Ludwigs-Universität Freiburg im Breisgau

All articles from Information Technology >>>

The most recent press releases about innovation >>>

Die letzten 5 Focus-News des innovations-reports im Überblick:

Im Focus: A bit of a stretch... material that thickens as it's pulled

Scientists have discovered the first synthetic material that becomes thicker - at the molecular level - as it is stretched.

Researchers led by Dr Devesh Mistry from the University of Leeds discovered a new non-porous material that has unique and inherent "auxetic" stretching...

Im Focus: The force of the vacuum

Scientists from the Theory Department of the Max Planck Institute for the Structure and Dynamics of Matter (MPSD) at the Center for Free-Electron Laser Science (CFEL) in Hamburg have shown through theoretical calculations and computer simulations that the force between electrons and lattice distortions in an atomically thin two-dimensional superconductor can be controlled with virtual photons. This could aid the development of new superconductors for energy-saving devices and many other technical applications.

The vacuum is not empty. It may sound like magic to laypeople but it has occupied physicists since the birth of quantum mechanics.

Im Focus: A golden age for particle analysis

Process engineers at Friedrich-Alexander-Universität Erlangen-Nürnberg (FAU) have developed a method which allows the size and shape of nanoparticles in dispersions to be determined considerably quicker than ever before. Based on gold nanorods, they demonstrated how length and diameter distributions can be measured accurately in just one step instead of the complicated series of electron microscopic images which have been needed up until now. Nanoparticles from precious metals are used, for example, as catalysts and contrast agents for diagnosing cancer. The results have been published in the renowned journal Nature Communications (doi: 10.1038/s41467-018-07366-9).

Even in the Middle Ages, gold particles were used to create vibrant red and blue colours, for example to illustrate biblical scenes in stained glass windows....

Im Focus: Successful second round of experiments with Wendelstein 7-X

The experiments conducted from July until November at the Wendelstein 7-X fusion device at the Max Planck Institute for Plasma Physics (IPP) in Greifswald have achieved higher values for the density and the energy content of the plasma and long discharge times of up to 100 seconds – record results for devices of the stellarator type. Meanwhile, the next round of the step-by-step upgrading of Wendelstein 7-X has begun. It is to equip the device for greater heating power and longer discharges. Wendelstein 7-X, the world’s largest fusion device of the stellarator type, is to investigate the suitability of this configuration for use in a power plant.

During the course of the step-by-step upgrading of Wendelstein 7-X, the plasma vessel was fitted with inner cladding since September of last year.

Im Focus: New process discovered: Mere sunlight can be used to eradicate pollutants in water

Advances in environmental technology: You don’t need complex filters and laser systems to destroy persistent pollutants in water. Chemists at Martin Luther University Halle-Wittenberg (MLU) have developed a new process that works using mere sunlight. The process is so simple that it can even be conducted outdoors under the most basic conditions. The chemists present their research in the journal “Chemistry - a European Journal”.

The chemists at MLU rely on electrons moving freely in water, so-called hydrated electrons, to degrade dissolved pollutants.

All Focus news of the innovation-report >>>

Anzeige

Anzeige

VideoLinks
Industry & Economy
Event News

Expert Panel on the Future of HPC in Engineering

03.12.2018 | Event News

Inaugural "Virtual World Tour" scheduled for december

28.11.2018 | Event News

Top-class programme at the ROS-Industrial Conference 2018

23.11.2018 | Event News

 
Latest News

A bit of a stretch... material that thickens as it's pulled

04.12.2018 | Materials Sciences

To detect new odors, fruit fly brains improve on a well-known computer algorithm

04.12.2018 | Life Sciences

New technique to identify phloem cells aids in the fight against citrus greening

04.12.2018 | Life Sciences

VideoLinks
Science & Research
Overview of more VideoLinks >>>