Analysis and simulation of the multiple resistive switching modes occurring in HfO<i>x</i>-based resistive random access memories using memdiodes

Petzold, Stefan; Miranda, E.; Sharath, Sankaramangalam Ulhas; Muñoz-Gorriz, J.; Vogel, Tobias; Piros, Eszter; Kaiser, Nico; Eilhardt, Robert; Zintler, Alexander; Molina‐Luna, Leopoldo; Suñé, J.; Alff, Lambert

doi:10.1063/1.5094864

Cited by 31 publications

(29 citation statements)

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“…This model is called the quasi-static memdiode model (QMM) and is the central subject of our analysis. Remarkably, the QMM has been explored so far as a single device or as simple series/anti-series/parallel/antiparallel connections (just two devices) [39]- [41], and its application to the case of large CPAs for pattern recognition tasks is still to be addressed. This is the central topic of this work.…”

Section: Introductionmentioning

confidence: 99%

Application of the Quasi-Static Memdiode Model in Cross-Point Arrays for Large Dataset Pattern Recognition

et al. 2020

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We investigate the use and performance of the quasi-static memdiode model (QMM) when incorporated into large cross-point arrays intended for pattern classification tasks. Following Chua's memristive devices theory, the QMM comprises two equations, one equation for the electron transport based on the doublediode circuit with single series resistance and a second equation for the internal memory state of the device based on the so-called logistic hysteron or memory map. Ex-situ trained memdiodes with different MNISTlike databases are used to establish the synaptic weights linking the top and bottom wire networks. The role played by the memdiode electrical parameters, wire resistance and capacitance values, image pixelation, connection schemes, signal-to-noise ratio and device-to-device variability in the classification effectiveness are investigated. The confusion matrix is used to benchmark the system performance metrics. We show that the simplicity, accuracy and robustness of the memdiode model makes it a suitable candidate for the realistic simulation of large-scale neural networks with non-idealities.

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Section: Introductionmentioning

confidence: 99%

Application of the Quasi-Static Memdiode Model in Cross-Point Arrays for Large Dataset Pattern Recognition

et al. 2020

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“…[11,12] This can be referred to as 3D RS. [14][15][16][17] In addition, the choice between digital and analog operation modes by different device initialization schemes has been reported for NiO-based devices. [13] Another type of area-dependent RS exists when ions are exchanged (or trapping occurs at the interface) between the switching matrix and the electrode.…”

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confidence: 99%

“…[14][15][16][17] In addition, the choice between digital and analog operation modes by different device initialization schemes has been reported for NiO-based devices. The direction of the switching loops is opposite to 1D RS and 3D RS, that is, eightwise (8w) when the bias is applied to the current blocking electrode.…”

mentioning

confidence: 99%

2D Resistive Switching Based on Amorphous Zinc–Tin Oxide Schottky Diodes

Branca

Deuermeier

Martins

et al. 2019

Adv Elect Materials

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of less destructive switching events, since the device reliability is independent of the reproducibility of the filament formation. [6] Frequently, an analog switching is observed, which is applicable for neuromorphic systems. [7][8][9][10] Reports exist in the literature, which explore area-dependent switching involving the homogeneous migration of defects or ions through the thickness of the switching matrix. [11,12] This can be referred to as 3D RS. In a device with asymmetric electrodes, both 1D RS and 3D RS result in counter eightwise (c8w) switching loops, when the bias is applied to the current blocking electrode. [13] Another type of area-dependent RS exists when ions are exchanged (or trapping occurs at the interface) between the switching matrix and the electrode. If the current transport through this interface is modulated as a consequence of the ion exchange/trapping, then this can be referred to as 2D RS. The direction of the switching loops is opposite to 1D RS and 3D RS, that is, eightwise (8w) when the bias is applied to the current blocking electrode. Frequently, 2D volatile switching has been observed as a secondary process, affecting the high resistive state (HRS) of an otherwise 1D RS device. [14][15][16][17] In addition, the choice between digital and analog operation modes by different device initialization schemes has been reported for NiO-based devices. [18] However, the resistance window for the analog mode was below one order of magnitude and the mechanism was discussed as 3D RS.Both in 3D RS and 2D RS, the active interface represents a barrier to the current flow, for example, a Schottky junction. [19] In the case of Ti/Pr 0.7 Ca 0.3 MnO 3 (PCMO) devices the underlying mechanism is based on a redox reaction between the titanium oxide interlayer and the PCMO. [20,21] In oxide-based devices with a platinum Schottky barrier bottom electrode, electronic trapping at interface states was proposed as a mechanism. [15] To allow a sizeable data retention, structural stabilization of the trapped charge needs to occur. [22] To achieve a high ratio between HRS and low resistance state (LRS) in 3D and 2D RS, a highly mobile Fermi level, that is, a highly variable charge carrier concentration is desirable. In thin-film transistors (TFT), AOS are known to yield tremendously high on/off ratios. [23] Diodes of AOS have rectification ratios of 10 6 . [24] These applications show how the material is able to change from an insulator to a metallic conductor by A room-temperature-processed resistive switching Schottky diode that can be operated in two distinct modes, depending solely on the choice of device initialization mode, is presented. Electroforming in the diode's reverse polarity leads to an abrupt filamentary switching with inherently long data retention at the expense of rectification. After this electroforming process, the devices may work in either a bipolar or unipolar manner with a resistance window of at least two orders of magnitude. Device initialization in the forward direction shows a smoo...

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“…The exact mechanisms, role of interfaces and nature of the conducting filament is still under debate. [14][15][16][17] When the size of the conducting filament reduces to the atomic scale, eventually conductance quantization phenomena may be observed even at room temperature. The quantum conductance unit is defined as G 0 = 2e 2 /h, [18] where e is the electron charge and h the Planck constant, and equals 77 µS or (12.9 kΩ) −1 .…”

Section: This Work Investigates the Transition From Digital To Graduamentioning

confidence: 99%

Tailoring the Switching Dynamics in Yttrium Oxide‐Based RRAM Devices by Oxygen Engineering: From Digital to Multi‐Level Quantization toward Analog Switching

Petzold

Piros

Eilhardt

et al. 2020

Adv Elect Materials

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Program under grant no. 805359-FOXON are gratefully acknowledged. E.M. also acknowledges the funding from the WAKeMeUP project as well as the support from the Ministerio de Ciencia, Innovación y Universidades, Spain (TEC2017-84321-C4-4-R and PCI2018-093107). Thanks to Katrin Walter for carrying out the UV/vis measurements and to Seyma Topcu for obtaining the current-voltage curves. S.P. and E.P. have equally contributed to the paper. Open access funding enabled and organized by Projekt DEAL.

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Analysis and simulation of the multiple resistive switching modes occurring in HfOx-based resistive random access memories using memdiodes

Cited by 31 publications

References 31 publications

Application of the Quasi-Static Memdiode Model in Cross-Point Arrays for Large Dataset Pattern Recognition

Application of the Quasi-Static Memdiode Model in Cross-Point Arrays for Large Dataset Pattern Recognition

2D Resistive Switching Based on Amorphous Zinc–Tin Oxide Schottky Diodes

Tailoring the Switching Dynamics in Yttrium Oxide‐Based RRAM Devices by Oxygen Engineering: From Digital to Multi‐Level Quantization toward Analog Switching

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