Complex materials can self-organize into circuits, may form basis for multifunction chips
Researchers studying the behavior of nanoscale materials at the Department of Energy's Oak Ridge National Laboratory have uncovered remarkable behavior that could advance microprocessors beyond today's silicon-based chips.
The study, featured on the cover of Advanced Electronic Materials, shows that a single crystal complex oxide material, when confined to micro- and nanoscales, can act like a multi-component electrical circuit. This behavior stems from an unusual feature of certain complex oxides called phase separation, in which tiny regions in the material exhibit vastly different electronic and magnetic properties.
It means individual nanoscale regions in complex oxide materials can behave as self-organized circuit elements, which could support new multifunctional types of computing architectures.
"Within a single piece of material, there are coexisting pockets of different magnetic and/or electronic behaviors," said ORNL's Zac Ward, the study's corresponding author. "What was interesting in this study was that we found we can use those phases to act like circuit elements. The fact that it is possible to also move these elements around offers the intriguing opportunity of creating rewritable circuitry in the material."
Because the phases respond to both magnetic and electrical fields, the material can be controlled in multiple ways, which creates the possibility for new types of computer chips.
"It's a new way of thinking about electronics, where you don't just have electrical fields switching off and on for your bits," Ward said. "This is not going for raw power. It's looking to explore completely different approaches towards multifunctional architectures where integration of multiple outside stimuli can be done in a single material."
As the computing industry looks to move past the limits of silicon-based chips, the ORNL proof-of-principle experiment shows that phase separated materials could be a way beyond the "one-chip-fits-all" approach. Unlike a chip that performs only one role, a multifunctional chip could handle several inputs and outputs that are tailored to the needs of a specific application.
"Typically you would need to link several different components together on a computer board if you wanted access to multiple outside senses," Ward said. "One big difference in our work is that we show certain complex materials already have these components built in, which may cut down on size and power requirements."
The researchers demonstrated their approach on a material called LPCMO, but Ward notes that other phase-separated materials have different properties that engineers could tap into.
"The new approach aims to increase performance by developing hardware around intended applications," he said. "This means that materials and architectures driving supercomputers, desktops, and smart phones, which each have very different needs, would no longer be forced to follow a one-chip-fits-all approach."
The study is published as "Multimodal Responses of Self-Organized Circuitry in Electronically Phase Separated Materials." Coauthors are Andreas Herklotz, Hangwen Guo, Anthony Wong, Ho Nyung Lee, Philip Rack and Thomas (Zac) Ward.
The work was supported by DOE's Office of Science and used resources at the ORNL's Center for Nanophase Materials Sciences, which is a DOE Office of Science User Facility.
UT-Battelle manages ORNL for the DOE's Office of Science. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit http://science.energy.gov/.
Thomas Zac Ward