Litcius/Paper detail

Ag-doped non–imperfection-enabled uniform memristive neuromorphic device based on van der Waals indium phosphorus sulfide

Yesheng Li, Yao Xiong, Baoxing Zhai, Lei Yin, Yiling Yu, Hao Wang, Jun He

2024Science Advances28 citationsDOIOpen Access PDF

Abstract

Memristors are considered promising energy-efficient artificial intelligence hardware, which can eliminate the von Neumann bottleneck by parallel in-memory computing. The common imperfection-enabled memristors are plagued with critical variability issues impeding their commercialization. Reported approaches to reduce the variability usually sacrifice other performances, e.g., small on/off ratios and high operation currents. Here, we demonstrate an unconventional Ag-doped nonimperfection diffusion channel–enabled memristor in van der Waals indium phosphorus sulfide, which can combine ultralow variabilities with desirable metrics. We achieve operation voltage, resistance, and on/off ratio variations down to 3.8, 2.3, and 6.9% at their extreme values of 0.2 V, 10 11 ohms, and 10 8 , respectively. Meanwhile, the operation current can be pushed from 1 nA to 1 pA at the scalability limit of 6 nm after Ag doping. Fourteen Boolean logic functions and convolutional image processing are successfully implemented by the memristors, manifesting the potential for logic-in-memory devices and efficient non–von Neumann accelerators.

Topics & Concepts

MemristorIndiumBottleneckScalabilityNeuromorphic engineeringMaterials scienceVon Neumann architecturevan der Waals forceComputer scienceOptoelectronicsDopingSulfideNanotechnologyPhysicsElectrical engineeringArtificial neural networkArtificial intelligenceEngineeringEmbedded systemQuantum mechanicsDatabaseMoleculeOperating systemMetallurgyAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance DevicesPerovskite Materials and Applications