TY - JOUR
T1 - Quantum Conductance in Memristive Devices
T2 - Fundamentals, Developments, and Applications
AU - Milano, Gianluca
AU - Aono, Masakazu
AU - Boarino, Luca
AU - Celano, Umberto
AU - Hasegawa, Tsuyoshi
AU - Kozicki, Michael
AU - Majumdar, Sayani
AU - Menghini, Mariela
AU - Miranda, Enrique
AU - Ricciardi, Carlo
AU - Tappertzhofen, Stefan
AU - Terabe, Kazuya
AU - Valov, Ilia
N1 - Publisher Copyright: © 2022 The Authors. Advanced Materials published by Wiley-VCH GmbH.
PY - 2022/8/11
Y1 - 2022/8/11
N2 - Quantum effects in novel functional materials and new device concepts represent a potential breakthrough for the development of new information processing technologies based on quantum phenomena. Among the emerging technologies, memristive elements that exhibit resistive switching, which relies on the electrochemical formation/rupture of conductive nanofilaments, exhibit quantum conductance effects at room temperature. Despite the underlying resistive switching mechanism having been exploited for the realization of next-generation memories and neuromorphic computing architectures, the potentialities of quantum effects in memristive devices are still rather unexplored. Here, a comprehensive review on memristive quantum devices, where quantum conductance effects can be observed by coupling ionics with electronics, is presented. Fundamental electrochemical and physicochemical phenomena underlying device functionalities are introduced, together with fundamentals of electronic ballistic conduction transport in nanofilaments. Quantum conductance effects including quantum mode splitting, stability, and random telegraph noise are analyzed, reporting experimental techniques and challenges of nanoscale metrology for the characterization of memristive phenomena. Finally, potential applications and future perspectives are envisioned, discussing how memristive devices with controllable atomic-sized conductive filaments can represent not only suitable platforms for the investigation of quantum phenomena but also promising building blocks for the realization of integrated quantum systems working in air at room temperature.
AB - Quantum effects in novel functional materials and new device concepts represent a potential breakthrough for the development of new information processing technologies based on quantum phenomena. Among the emerging technologies, memristive elements that exhibit resistive switching, which relies on the electrochemical formation/rupture of conductive nanofilaments, exhibit quantum conductance effects at room temperature. Despite the underlying resistive switching mechanism having been exploited for the realization of next-generation memories and neuromorphic computing architectures, the potentialities of quantum effects in memristive devices are still rather unexplored. Here, a comprehensive review on memristive quantum devices, where quantum conductance effects can be observed by coupling ionics with electronics, is presented. Fundamental electrochemical and physicochemical phenomena underlying device functionalities are introduced, together with fundamentals of electronic ballistic conduction transport in nanofilaments. Quantum conductance effects including quantum mode splitting, stability, and random telegraph noise are analyzed, reporting experimental techniques and challenges of nanoscale metrology for the characterization of memristive phenomena. Finally, potential applications and future perspectives are envisioned, discussing how memristive devices with controllable atomic-sized conductive filaments can represent not only suitable platforms for the investigation of quantum phenomena but also promising building blocks for the realization of integrated quantum systems working in air at room temperature.
KW - ballistic transport
KW - memristive devices
KW - quantized conductance
KW - quantum conductance
KW - resistive switching
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U2 - 10.1002/adma.202201248
DO - 10.1002/adma.202201248
M3 - Review article
C2 - 35404522
SN - 0935-9648
VL - 34
JO - Advanced Materials
JF - Advanced Materials
IS - 32
M1 - 2201248
ER -