Phase-change heterostructure enables ultralow noise and drift for memory operation

Keyuan Ding; Jiangjing Wang; Yuxing Zhou; He Tian; Lu L. Lu; Riccardo Mazzarello; Chunlin Jia; Wei Zhang; Feng Rao; Evan Ma

doi:10.1126/science.aay0291

Phase-change heterostructure enables ultralow noise and drift for memory operation

Keyuan Ding
, Jiangjing Wang
, Yuxing Zhou
, He Tian
, Lu L. Lu
, Riccardo Mazzarello
, Chunlin Jia
, Wei Zhang
, Feng Rao
, Evan Ma

Shenzhen University
Yulin University
Xi'an Jiaotong University
Zhejiang University
RWTH Aachen University
Jülich Research Centre
CAS - Shanghai Institute of Microsystem and Information Technology
Johns Hopkins University

Research output: Contribution to journal › Article › peer-review

379 Scopus citations

Abstract

Artificial intelligence and other data-intensive applications have escalated the demand for data storage and processing. New computing devices, such as phase-change random access memory (PCRAM)–based neuro-inspired devices, are promising options for breaking the von Neumann barrier by unifying storage with computing in memory cells. However, current PCRAM devices have considerable noise and drift in electrical resistance that erodes the precision and consistency of these devices. We designed a phase-change heterostructure (PCH) that consists of alternately stacked phase-change and confinement nanolayers to suppress the noise and drift, allowing reliable iterative RESET and cumulative SET operations for high-performance neuro-inspired computing. Our PCH architecture is amenable to industrial production as an intrinsic materials solution, without complex manufacturing procedure or much increased fabrication cost.

Original language	English
Pages (from-to)	210-215
Number of pages	6
Journal	Science
Volume	366
Issue number	6462
DOIs	https://doi.org/10.1126/science.aay0291
State	Published - 11 Oct 2019

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abstract = "Artificial intelligence and other data-intensive applications have escalated the demand for data storage and processing. New computing devices, such as phase-change random access memory (PCRAM)–based neuro-inspired devices, are promising options for breaking the von Neumann barrier by unifying storage with computing in memory cells. However, current PCRAM devices have considerable noise and drift in electrical resistance that erodes the precision and consistency of these devices. We designed a phase-change heterostructure (PCH) that consists of alternately stacked phase-change and confinement nanolayers to suppress the noise and drift, allowing reliable iterative RESET and cumulative SET operations for high-performance neuro-inspired computing. Our PCH architecture is amenable to industrial production as an intrinsic materials solution, without complex manufacturing procedure or much increased fabrication cost.",

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AU - Ding, Keyuan

AU - Wang, Jiangjing

AU - Zhou, Yuxing

AU - Tian, He

AU - Lu, Lu L.

AU - Mazzarello, Riccardo

AU - Jia, Chunlin

AU - Zhang, Wei

AU - Rao, Feng

AU - Ma, Evan

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N2 - Artificial intelligence and other data-intensive applications have escalated the demand for data storage and processing. New computing devices, such as phase-change random access memory (PCRAM)–based neuro-inspired devices, are promising options for breaking the von Neumann barrier by unifying storage with computing in memory cells. However, current PCRAM devices have considerable noise and drift in electrical resistance that erodes the precision and consistency of these devices. We designed a phase-change heterostructure (PCH) that consists of alternately stacked phase-change and confinement nanolayers to suppress the noise and drift, allowing reliable iterative RESET and cumulative SET operations for high-performance neuro-inspired computing. Our PCH architecture is amenable to industrial production as an intrinsic materials solution, without complex manufacturing procedure or much increased fabrication cost.

AB - Artificial intelligence and other data-intensive applications have escalated the demand for data storage and processing. New computing devices, such as phase-change random access memory (PCRAM)–based neuro-inspired devices, are promising options for breaking the von Neumann barrier by unifying storage with computing in memory cells. However, current PCRAM devices have considerable noise and drift in electrical resistance that erodes the precision and consistency of these devices. We designed a phase-change heterostructure (PCH) that consists of alternately stacked phase-change and confinement nanolayers to suppress the noise and drift, allowing reliable iterative RESET and cumulative SET operations for high-performance neuro-inspired computing. Our PCH architecture is amenable to industrial production as an intrinsic materials solution, without complex manufacturing procedure or much increased fabrication cost.

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Phase-change heterostructure enables ultralow noise and drift for memory operation

Abstract

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