Impedance Spectroscopy on Hafnium Oxide‐Based Memristive Devices

Marquardt, Richard; Zahari, Finn; Carstensen, Jürgen; Popkirov, G.; Gronenberg, Ole; Kolhatkar, Gitanjali; Kohlstedt, H.; Ziegler, Martin

doi:10.1002/aelm.202201227

Cited by 9 publications

(3 citation statements)

References 81 publications

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“…The worked-out model is in agreement with the companion paper Marquardt et al that exploits ImpSpec to probe the current transport and switching kinetics of the same devices. [74] Based on two different experimental approaches (XPS/HAXPES and ImpSpec), our findings strongly indicate an electronic charging and discharging of traps as the fundamental origin of resistive switching in our devices, instead of ionic drift.…”

Section: Discussionmentioning

confidence: 52%

“…This is consistent with the results of ImpSpec conducted on the reference devices, performed by Marquardt et al and reported in the companion paper. [74] Here, the kinetics of the set process and of the retention imply charging of traps rather than ion movement. Furthermore, quantitative model parameters describing current transport in HRS and LRS and switching dynamics are given.…”

Section: Device Modelmentioning

confidence: 99%

“…Spectroscopic evidence (by XPS/HAXPES) for such a switching mechanism has not been reported so far. Furthermore, impedance spectroscopy (ImpSpec) [73] is exploited by Marquardt et al in a companion paper [74] to probe memristive switching in the same device. The findings presented in both papers indicate that the memristive switching can be attributed to a Schottky barrier modulation by a charge-trapping mechanism.…”

Section: Introductionmentioning

confidence: 99%

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Trap‐Assisted Memristive Switching in HfO₂‐Based Devices Studied by In Situ Soft and Hard X‐Ray Photoelectron Spectroscopy

Zahari

Marquardt

Kalläne

et al. 2023

Adv Elect Materials

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Memristive devices are under intense development as non‐volatile memory elements for extending the computing capabilities of traditional silicon technology by enabling novel computing primitives. In this respect, interface‐based memristive devices are promising candidates to emulate synaptic functionalities in neuromorphic circuits aiming to replicate the information processing of nervous systems. A device composed of Nb/NbOx/Al2O3/HfO2/Au that shows promising features like analog switching, no electro‐forming, and high current‐voltage non‐linearity is reported. Synchrotron‐based X‐ray photoelectron spectroscopy and depth‐dependent hard X‐ray photoelectron spectroscopy are used to probe in situ different resistance states and thus the origin of memristive switching. Spectroscopic evidence for memristive switching based on the charge state of electron traps within HfO2 is found. Electron energy loss spectroscopy and transmission electron microscopy support the analysis. A device model is proposed that considers a two‐terminal metal–insulator–semiconductor structure in which traps within the insulator (HfO2/Al2O3) modulate the space charge region within the semiconductor (NbOx) and, thereby, the overall resistance. The experimental findings are in line with impedance spectroscopy data reported in the companion paper (Marquardt et al). Both works complement one another to derive a detailed device model, which helps to engineer device performance and integrate devices into silicon technology.

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Section: Discussionmentioning

confidence: 52%

Section: Device Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Trap‐Assisted Memristive Switching in HfO₂‐Based Devices Studied by In Situ Soft and Hard X‐Ray Photoelectron Spectroscopy

Zahari

Marquardt

Kalläne

et al. 2023

Adv Elect Materials

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The Role of Hydrogen in ReRAM

Cox,

Sharpe,

McAleese

et al. 2024

Advanced Materials

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Previous research on transistor gate oxides reveals a clear link between hydrogen content and oxide breakdown. This has implications for redox‐based resistive random access memory (ReRAM) devices, which exploit soft, reversible, dielectric breakdown, as hydrogen is often not considered in modeling or measured experimentally. Here quantitative measurements, corroborated across multiple techniques are reported, that reveal ReRAM devices, whether manufactured in a university setting or research foundry, contain concentrations of hydrogen at levels likely to impact resistance switching behavior. To the knowledge this is the first empirical measurement depth profiling hydrogen concentration through a ReRAM device. Applying a recently‐developed Secondary Ion Mass Spectrometry analysis technique enables to measure hydrogen diffusion across the interfaces of SiOx ReRAM devices as a result of operation. These techniques can be applied to a broad range of devices to further understand ReRAM operation. Careful control of temperatures, precursors, and exposure to ambient during fabrication should limit hydrogen concentration. Additionally, using thin oxynitride or TiO2 capping layers should prevent diffusion of hydrogen and other contaminants into devices during operation. Applying these principles to ReRAM devices will enable considerable, informed, improvements in performance.

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Printed High‐Entropy Prussian Blue Analogs for Advanced Non‐Volatile Memristive Devices

He,

Ting,

et al. 2024

Advanced Materials

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Non‐volatile memristors dynamically switch between high (HRS) and low resistance states (LRS) in response to electrical stimuli, essential for electronic memories, neuromorphic computing, and artificial intelligence. High‐entropy Prussian blue analogs (HE‐PBAs) are promising insertion‐type battery materials due to their diverse composition, high structural integrity, and favorable ionic conductivity. This work proposes a non‐volatile, bipolar memristor based on HE‐PBA. The device, featuring an active layer of HE‐PBA sandwiched between Ag and ITO electrodes, is fabricated by inkjet printing and microplotting. The conduction mechanism of the Ag/HE‐PBA/ITO device is systematically investigated. The results indicate that the transition between HRS and LRS is driven by an insulating‐metallic transition, triggered by extraction/insertion of highly mobile Na+ ions upon application of an electric field. The memristor operates through a low‐energy process akin to Na+ shuttling in Na‐ion batteries rather than depending on formation/rupture of Ag filaments. Notably, it showcases promising characteristics, including non‐volatility, self‐compliance, and forming‐free behavior, and further exhibits low operation voltage (VSET = −0.26 V, VRESET = 0.36 V), low power consumption (PSET = 26 µW, PRESET = 8.0 µW), and a high ROFF/RON ratio of 104. This underscores the potential of high‐entropy insertion materials for developing printed memristors with distinct operation mechanisms.

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Impedance Spectroscopy on Hafnium Oxide‐Based Memristive Devices

Cited by 9 publications

References 81 publications

Trap‐Assisted Memristive Switching in HfO₂‐Based Devices Studied by In Situ Soft and Hard X‐Ray Photoelectron Spectroscopy

Trap‐Assisted Memristive Switching in HfO₂‐Based Devices Studied by In Situ Soft and Hard X‐Ray Photoelectron Spectroscopy

The Role of Hydrogen in ReRAM

Printed High‐Entropy Prussian Blue Analogs for Advanced Non‐Volatile Memristive Devices

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Impedance Spectroscopy on Hafnium Oxide‐Based Memristive Devices

Cited by 9 publications

References 81 publications

Trap‐Assisted Memristive Switching in HfO2‐Based Devices Studied by In Situ Soft and Hard X‐Ray Photoelectron Spectroscopy

Trap‐Assisted Memristive Switching in HfO2‐Based Devices Studied by In Situ Soft and Hard X‐Ray Photoelectron Spectroscopy

The Role of Hydrogen in ReRAM

Printed High‐Entropy Prussian Blue Analogs for Advanced Non‐Volatile Memristive Devices

Contact Info

Product

Resources

About

Trap‐Assisted Memristive Switching in HfO₂‐Based Devices Studied by In Situ Soft and Hard X‐Ray Photoelectron Spectroscopy

Trap‐Assisted Memristive Switching in HfO₂‐Based Devices Studied by In Situ Soft and Hard X‐Ray Photoelectron Spectroscopy