Thursday, March 21, 2013

IBM turns metal oxides - chips through liquid currents 2013

IBM is worried that we're reaching the end of the road for CMOS technology -- that we need new materials beyond silicon to keep the power draw down in chips as their performance goes up. It may keep future circuitry extra-lean through a new technique that puts a metal oxide in silicon's place and allows for non-volatileprocessors and memory. By running ionized liquid electrolytes in currents through the oxide, the company can switch that oxide from an insulator to a conductor (and vice versa) that can reliably maintain its state, even when there's no power. The trick would let a logic gate or switch kick into action only when there's an event, rather than needing constant jolts of electricity -- and without the pressure or temperature changes that had ruled out metal oxides for chips in the past. We're still far from replacing silicon with more efficient oxides given the early state of IBM's work, but having a consistent method is an important first step.
IBM technique turns metal oxides into nonvolatile memory through liquids
Made in IBM Labs: Scientists Discover New Molecular Technique to Charge Memory Chips
San Jose, Calif., – 22 March, 2013: IBM (NYSE: IBM) today announced a materials science breakthrough at the molecular level that could pave the way for a new class of non-volatile memory and logic chips that would use less power than today's silicon devices like cell phones. Rather than using conventional electrical means to charge today's semiconductors, IBM's scientists discovered a new way to power chips using tiny ionic currents, which are streams of charged molecules that can mimic the event-driven way in which the human brain operates.
Today's computers typically use semiconductors made with CMOS process technology and it was long thought that these chips would double in performance and decrease in size and cost every two years. But the materials and techniques to develop and build CMOS chips are rapidly approaching physical and performance limitations and new solutions may soon be needed to develop high performance and low-power devices.
The IBM research scientists were the first to convert metal oxides from an insulated to conductive state using the insertion and removal of oxygen ions during the material characterization process. Once the material becomes a conductor, the IBM experiment showed the non-volatile memory chip would maintain a stable metallic state even if the power to a device is turned off. This non-volatile characteristic means the chip could be used to store and transport data in a more efficient, event-driven manner instead of requiring the silicon to be constantly charged on and off by an electrical current.
"Our unique ability to understand and control matter at molecular dimensions enables us to come up with new materials that could one day stand in for silicon based technologies," said Dr. Stuart Parkin, an IBM Fellow at IBM Research. "We're writing a new chapter in the future of computing with innovations – including looking beyond traditional electrically charge-based devices - to prevent the industry from hitting a technology brick wall."
To achieve this breakthrough, IBM researchers applied a positively charged ionic liquid electrolyte to an insulated oxide material and successfully converted the material to a conducting metal. The material held its metallic state until a negatively charged ionic liquid electrolyte was applied, to convert it back to its original, insulating state.
Metal to insulator transition materials have existed and been researched for years, however, contrary to earlier conclusions, IBM discovered it was the removal and injection of oxygen molecules into the metal oxides that was responsible for the state changes in the material. The transition from a conducting state to an insulating state was previously achieved by changing the temperature or applying an external stress, both of which do not lend themselves easily to making chips.
This research was published yesterday in the peer-reviewed journal Science.

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