Abstract
Inspired by the great success of fiber optics in ultrafast data transmission, photonic computing is being extensively studied as an alternative to replace or hybridize electronic computers, which are reaching speed and bandwidth limitations. Mimicking and implementing basic computing elements on photonic devices is a first and essential step toward all-optical computers. Here, an optical pulse-width modulation (PWM) switching of phase-change materials on an integrated waveguide is developed, which allows practical implementation of photonic memories and logic devices. It is established that PWM with low peak power is very effective for recrystallization of phase-change materials, in terms of both energy efficiency and process control. Using this understanding, multilevel photonic memories with complete random accessibility are then implemented. Finally, programmable optical logic devices are demonstrated conceptually and experimentally, with logic "OR" and "NAND" achieved on just a single integrated photonic phase-change cell. This study provides a practical and elegant technique to optically program photonic phase-change devices for computing applications.
Highlights
COPYRIGHT AND REUSE Open Research Exeter makes this work available in accordance with publisher policies
Phase-change material (PCM) based photonic memories have recently emerged as a leading candidate to offer true nonvolatility.[24]
The qualitative finite-difference time-domain (FDTD)/finite element method (FEM) simulations have indicated the direction for optimizing the switching of GST, we used empirical methods to choose the parameters of optical pulses for experimental implementation of photonic memories and logic devices below
Summary
COPYRIGHT AND REUSE Open Research Exeter makes this work available in accordance with publisher policies. Device-Level Photonic Memories and Logic Applications Using Phase-Change Materials
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