AI Article Synopsis
- Neuromorphic computing offers faster and more energy-efficient AI computations than traditional digital computers, but currently lacks accuracy compared to software-based AI.
- The study focuses on enhancing accuracy by managing the randomness of memristive devices, which mimic brain synapses, through controlled conduction channel formation via electrode design.
- Using techniques like X-ray imaging and molecular dynamics simulations, researchers demonstrate that careful electrode design can achieve a consistent distribution of oxygen vacancies, leading to improved memristive device performance in neuromorphic computing.
Article Abstract
Neuromorphic computing provides a means for achieving faster and more energy efficient computations than conventional digital computers for artificial intelligence (AI). However, its current accuracy is generally less than the dominant software-based AI. The key to improving accuracy is to reduce the intrinsic randomness of memristive devices, emulating synapses in the brain for neuromorphic computing. Here using a planar device as a model system, the controlled formation of conduction channels is achieved with high oxygen vacancy concentrations through the design of sharp protrusions in the electrode gap, as observed by X-ray multimodal imaging of both oxygen stoichiometry and crystallinity. Classical molecular dynamics simulations confirm that the controlled formation of conduction channels arises from confinement of the electric field, yielding a reproducible spatial distribution of oxygen vacancies across switching cycles. This work demonstrates an effective route to control the otherwise random electroforming process by electrode design, facilitating the development of more accurate memristive devices for neuromorphic computing.
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| http://dx.doi.org/10.1002/adma.202203209 | DOI Listing |
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