SPICE Implementation of the Dynamic Memdiode Model for Bipolar Resistive Switching Devices

Aguirre, Fernando; Suñé, J.; Miranda, E.

doi:10.3390/mi13020330

Cited by 32 publications

(39 citation statements)

References 79 publications

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“…The script used for modeling is reported in Supporting Information, Figure S7 and contains five parts: parameter definition, memory state equation, current–voltage characteristic for the memristive device, current–voltage characteristic for the nanowire, and auxiliary functions. The memristive behavior is based on an adaptation of the memdiode model for resistive switching devices reported in ref . The model includes the snapback effect and an internal series resistance.…”

Section: Methodsmentioning

confidence: 99%

Experimental and Modeling Study of Metal–Insulator Interfaces to Control the Electronic Transport in Single Nanowire Memristive Devices

Milano

Miranda

Fretto

et al. 2022

ACS Appl. Mater. Interfaces

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Memristive devices relying on redox-based resistive switching mechanisms represent promising candidates for the development of novel computing paradigms beyond von Neumann architecture. Recent advancements in understanding physicochemical phenomena underlying resistive switching have shed new light on the importance of an appropriate selection of material properties required to optimize the performance of devices. However, despite great attention has been devoted to unveiling the role of doping concentration, impurity type, adsorbed moisture, and catalytic activity at the interfaces, specific studies concerning the effect of the counter electrode in regulating the electronic flow in memristive cells are scarce. In this work, the influence of the metal–insulator Schottky interfaces in electrochemical metallization memory (ECM) memristive cell model systems based on single-crystalline ZnO nanowires (NWs) is investigated following a combined experimental and modeling approach. By comparing and simulating the electrical characteristics of single NW devices with different contact configurations and by considering Ag and Pt electrodes as representative of electrochemically active and inert electrodes, respectively, we highlight the importance of an appropriate choice of electrode materials by taking into account the Schottky barrier height and interface chemistry at the metal–insulator interfaces. In particular, we show that a clever choice of metal–insulator interfaces allows to reshape the hysteretic conduction characteristics of the device and to increase the device performance by tuning its resistance window. These results obtained from single NW-based devices provide new insights into the selection criteria for materials and interfaces in connection with the design of advanced ECM cells.

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Section: Methodsmentioning

confidence: 99%

Experimental and Modeling Study of Metal–Insulator Interfaces to Control the Electronic Transport in Single Nanowire Memristive Devices

Milano

Miranda

Fretto

et al. 2022

ACS Appl. Mater. Interfaces

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“…where I 0 and α are assumed to be linear functions of the memory state of the device λ. [164,165] In addition, notice that for α ! 0 (collapse of the confining barrier), ( 8) reduces again to I ¼ G 0 V. Since φ is assumed to be normally distributed, the current amplitude factor I 0 in ( 8) is lognormally distributed.…”

Section: Quantum Approach To Variability In Rramsmentioning

confidence: 99%

“…Further details about the Dynamic Memdiode Model can be found in refs. [164,165]. The model script is presented in Table 5.…”

Section: Application Of the Dynamic Memdiode Model To C2c Variabilitymentioning

confidence: 99%

Variability in Resistive Memories

Roldán

Miranda

Maldonado

et al. 2023

Advanced Intelligent Systems

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Research and development efforts in the nonvolatile memory arena are focused on a reduced set of innovative components, among which we can include memristors. [1,2] Memristors are expected to be key players in the electronics landscape of the coming years largely because of the powerful applications that stand upon their unique features. [1,[3][4][5] The switching mechanisms behind memristors differ significantly depending on the physical properties of the structures and the materials involved. [1,[3][4][5][6][7] To list some of these mechanisms, we can highlight those devices based on phase-change materials, which can be switched reversibly between amorphous and crystalline phases with different electrical resistivity (phasechange memories, PCMs); [8] devices that take advantage of the magnetic and electrical properties exhibited by some materials with different architectures (magnetic RAMs, MRAMs); [9] also structures where materials with switchable electrical polarization give rise to hysteresis curves of the polarization versus electrical field that can be engineered for storing information (ferroelectric FET, FFET); [10] and, finally, resistive RAMs (RRAMs) where the dielectric conduction properties are altered by means of the internal ion movement and concurrent redox reactions used to generate different resistive states. [1,3,11,12]

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“…R H 8 3 8 w q I l b g l 9 i / d N P O / O l W L R B 8 n u g a P a o o 1 o 6 p j m U u q u 6 J u b n 6 p S p J D T J z C P Y o L w k w r p 3 0 2 t S b R t a v e O j r + p j M V q / Y s y 0 3 x r m 5 J A 7 Z / j n M W N C p l + 6 h s X R y W q p V s 1 H n s Y B f 7 N M 9 j V H G G G u r k H e A R T 3 g 2 z g 1 p j I 3 J Z 6 q R y z T b + L a M h w 9 2 h Z I 1 < / l a t e x i t > w 1 1,2 < l a t e x i t s h a 1 _ b a s e 6 4 = " r b Let us briefly comment on the linearity of the memristor we are considering. According to the memdiode model [23], the I-V characteristic of a memristor reads as…”

Section: < L a T E X I T Smentioning

confidence: 99%

“…• To adjust the conductance values in G j,+ and G j,− (i.e., to decide which memristors are set to g H and which are set to g L ); Note that we consider devices operating in the linear regime (i.e., in the low-voltage region), and thus nonlinearities in the I-V characteristic can be disregarded [23]. Beyond this point, the conductance of the devices may change as we move to the programming region, which is out of the scope of this work.…”

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confidence: 99%

Ternary Neural Networks Based on on/off Memristors: Set-Up and Training

et al. 2022

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Neuromorphic systems based on hardware neural networks (HNNs) are expected to be an energy and time-efficient computing architecture for solving complex tasks. In this paper, we consider the implementation of deep neural networks (DNNs) using crossbar arrays of memristors. More specifically, we considered the case where such devices can be configured in just two states: the low-resistance state (LRS) and the high-resistance state (HRS). HNNs suffer from several non-idealities that need to be solved when mapping our software-based models. A clear example in memristor-based neural networks is conductance variability, which is inherent to resistive switching devices, so achieving good performance in an HNN largely depends on the development of reliable weight storage or, alternatively, mitigation techniques against weight uncertainty. In this manuscript, we provide guidelines for a system-level designer where we take into account several issues related to the set-up of the HNN, such as what the appropriate conductance value in the LRS is or the adaptive conversion of current outputs at one stage to input voltages for the next stage. A second contribution is the training of the system, which is performed via offline learning, and considering the hardware imperfections, which in this case are conductance fluctuations. Finally, the resulting inference system is tested in two well-known databases from MNIST, showing that is competitive in terms of classification performance against the software-based counterpart. Additional advice and insights on system tuning and expected performance are given throughout the paper.

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SPICE Implementation of the Dynamic Memdiode Model for Bipolar Resistive Switching Devices

Cited by 32 publications

References 79 publications

Experimental and Modeling Study of Metal–Insulator Interfaces to Control the Electronic Transport in Single Nanowire Memristive Devices

Experimental and Modeling Study of Metal–Insulator Interfaces to Control the Electronic Transport in Single Nanowire Memristive Devices

Variability in Resistive Memories

Ternary Neural Networks Based on on/off Memristors: Set-Up and Training

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