Electric‐Field‐Induced Resistive Switching in a Family of Mott Insulators: Towards a New Class of RRAM Memories

Cario, Laurent; Vaju, C.; Corraze, B.; Guiot, Vincent; Janod, Étienne

doi:10.1002/adma.201002521

Cited by 135 publications

(171 citation statements)

References 18 publications

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“…This value is too low to induce any significant increase of the temperature causing a thermaldriven switching 25 . For these reasons, we can conclude that the forming is electric field driven.…”

Section: Discussionmentioning

confidence: 99%

On the origin of resistive switching volatility in Ni/TiO2/Ni stacks

Cortese

Trapatseli

Khiat

et al. 2016

Journal of Applied Physics

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Resistive switching (RS) and Resistive Random Access Memories (ReRAMs) that exploit it have attracted huge interests for next generation non volatile memory (NVM) applications, also thought to be able to overcome flash memories limitations when arranged in crossbar arrays. A cornerstone of their potential success is that the RS between two different resistive states, usually High (HRS, High resistive state) and Low(LRS, Low Resistive State) is an intrinsic non-volatile phenomenon with the two states thermodynamically stable. Titanium Dioxide is one of the most common materials known to show non-volatile RS. In this paper we report the first observed volatile resistive switching (VRS) in a Titanium Dioxide thin film. The aim of this paper is to study and understand the VRS phenomenon to give an extensive picture of its underlying Physics. A possible exploitation of the VRS could be in access devices in ReRAM crossbar arrays.

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Section: Discussionmentioning

confidence: 99%

On the origin of resistive switching volatility in Ni/TiO2/Ni stacks

Cortese

Trapatseli

Khiat

et al. 2016

Journal of Applied Physics

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“…A 500-nm device array fabricated by photolithography is shown in Fig. 4a and a single (30 nm) 2 cell-size device fabricated by electron beam lithography is shown in Fig. 4b.…”

Section: -Xmentioning

confidence: 99%

“…4a. Meanwhile, cell-size devices of (250 nm) 2 , (100 nm) 2 , (50 nm) 2 and (30 nm) 2 in Fig. 4e were measured in a device structure as shown in Fig.…”

Section: -Xmentioning

confidence: 99%

“…It is required to improve the performance of both of these elements to achieve terabit density memory. Furthermore, both components will be required to be compatible with technologies such as threedimensional (3D) cell stacking, multi-level cell, endurance and scaling for future memory and switch devices 1,2 . Resistive random access memory has been considered to be one of the most promising candidates to overcome scaling limits of the conventional memory due to its scalability, data retention (nonvolatility), fast switching speed and low power consumption [3][4][5][6][7][8][9][10][11][12][13][14][15] .…”

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confidence: 99%

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A plasma-treated chalcogenide switch device for stackable scalable 3D nanoscale memory

et al. 2013

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Stackable select devices such as the oxide p-n junction diode and the Schottky diode (one-way switch) have been proposed for non-volatile unipolar resistive switching devices; however, bidirectional select devices (or two-way switch) need to be developed for bipolar resistive switching devices. Here we report on a fully stackable switching device that solves several problems including current density, temperature stability, cycling endurance and cycle distribution. We demonstrate that the threshold switching device based on As-Ge-Te-Si material significantly improves cycling endurance performance by reactive nitrogen deposition and nitrogen plasma hardening. Formation of the thin Si 3 N 4 glass layer by the plasma treatment retards tellurium diffusion during cycling. Scalability of threshold switching devices is measured down to 30 nm scale with extremely fast switching speed of B2 ns.

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“…Resistance memory devices based on the displacement or diffusion of ions, including resistive random access memory (ReRAM), [1][2][3] atomic switches, 4,5 and memristors, 6,7 have attracted great interest 8,9 because they offer low energy consumption, 10 simple structure, and fast switching; 11 moreover, they can be scaled down to ∼10 nm. Although such memory devices are promising candidates for the next-generation memory technologies, there is a strong demand for the development of memory devices with much lower energy consumption and even simpler structures.…”

mentioning

confidence: 99%

A nonvolatile memory device with very low power consumption based on the switching of a standard electrode potential

et al. 2017

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We prepared a nonvolatile memory device that could be reversibly switched between a high and a low open-circuit voltage (Voc) regime. The device is composed of a solid electrolyte Li3PO4 film sandwiched between metal Li and Au electrodes: a Li/Li3PO4/Au heterostructure, which was fabricated at room temperature on a glass substrate. The bistable states at Voc ∼ 0.7 and ∼0.3 V could be reversibly switched by applying an external voltage of 2.0 and 0.18 V, respectively. The formation and deformation of an ultrathin Au–Li alloy at the Li3PO4/Au electrode interface were the origin of the reversible switching.

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Electric‐Field‐Induced Resistive Switching in a Family of Mott Insulators: Towards a New Class of RRAM Memories

Cited by 135 publications

References 18 publications

On the origin of resistive switching volatility in Ni/TiO2/Ni stacks

On the origin of resistive switching volatility in Ni/TiO2/Ni stacks

A plasma-treated chalcogenide switch device for stackable scalable 3D nanoscale memory

A nonvolatile memory device with very low power consumption based on the switching of a standard electrode potential

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