Demonstration of high-density ReRAM ensuring 10-year retention at 85&amp;#x00B0;C based on a newly developed reliability model

Wei, Zhiqiang; Takagi, Toshihisa; Kanzawa, Yuchi; Katoh, Y.; Ninomiya, T.; Kawai, K.; Muraoka, S.; Mitani, S.; Kawasaki, Koji; Fujii, Satoshi; Miyanaga, Ryouko; Kawashima, Y.; Mikawa, Takumi; Shimakawa, K.; Aono, K.

doi:10.1109/iedm.2011.6131650

Cited by 108 publications

(110 citation statements)

References 5 publications

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“…The LRS conduction is believed to be governed by metallic conduction because of the Ohmic I-V characteristic and finite residual resistance at low temperature. In HRS, the I-V curve is well fitted to a straight line in ln(J) ∝ T Similar to [61], Zhang et al [64] also observed temperature dependency of the hopping conduction in TaOy/Ta2O5−x device. Two distinct slopes can be seen in the plot of ln(σ) against 1000/T.…”

Section: Hopping Conductionmentioning

confidence: 51%

“…While CF evolution is typically associated with thermal, electrical or ion migration [19,20], there is no consensus on the dominant conduction mechanism in resistive switching memory devices [21][22][23]. Among the commonly observed conduction mechanisms are: (i) Poole-Frenkel emission [24][25][26][27][28][29][30][31][32]; (ii) Schottky emission [33][34][35][36][37][38][39][40][41][42]; (iii) SCLC [43][44][45][46][47][48][49][50][51][52][53] (iv) trap-assisted tunneling [54][55][56][57][58][59]; and (v) hopping conduction [60][61][62][63][64][65]. To enhance the device performance and data retention property, it is crucial to identifying t...…”

Section: Introductionmentioning

confidence: 99%

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Conduction Mechanism of Valence Change Resistive Switching Memory: A Survey

2015

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Abstract:Resistive switching effect in transition metal oxide (TMO) based material is often associated with the valence change mechanism (VCM). Typical modeling of valence change resistive switching memory consists of three closely related phenomena, i.e., conductive filament (CF) geometry evolution, conduction mechanism and temperature dynamic evolution. It is widely agreed that the electrochemical reduction-oxidation (redox) process and oxygen vacancies migration plays an essential role in the CF forming and rupture process. However, the conduction mechanism of resistive switching memory varies considerably depending on the material used in the dielectric layer and selection of electrodes. Among the popular observations are the Poole-Frenkel emission, Schottky emission, space-charge-limited conduction (SCLC), trap-assisted tunneling (TAT) and hopping conduction. In this article, we will conduct a survey on several published valence change resistive switching memories with a particular interest in the I-V characteristic and the corresponding conduction mechanism.

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Section: Hopping Conductionmentioning

confidence: 51%

Section: Introductionmentioning

confidence: 99%

Conduction Mechanism of Valence Change Resistive Switching Memory: A Survey

2015

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“…[1,3] Various physical phenomena are known to lead to a non-volatile resistive switching effect which are related to different types of RRAM such as Thermo Chemical Memories (TCM) or Valency Change…”

Section: Introductionmentioning

confidence: 99%

Ge2Sb2Te5 layer used as solid electrolyte in conductive-bridge memory devices fabricated on flexible substrate

Deleruyelle

Putero

Ouled-Khachroum

et al. 2013

Solid-State Electronics

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This paper shows that the well-know chalcogenide Ge 2 Sb 2 Te 5 (GST) in its amorphous state may be advantageously used as solid electrolyte material to fabricate Conductive-Bridge Random Access Memory (CBRAM) devices. GST layer was sputtered on preliminary inkjet-printed silver lines acting as active electrode on either silicon or plastic substrates. Whatever the substrate, the resistance switching is unambiguously attested at a nanoscale by means of conductive-atomic force microscopy (C-AFM) using a Pt-Ir coated tip on the GST surface acting as a passive electrode. The resistance change is correlated to the appearance or disappearance of concomitant hillocks and current spots at the surface of the GST layer. This feature is attributed to the formation/dissolution of a silver-rich protrusion beneath the AFM tip during set/reset operation. Beside, this paper constitutes a step toward the elaboration of crossbar memory arrays on flexible substrates since CBRAM operations were demonstrated on W/GST/Ag crossbar memory cells obtained from an heterogeneous fabrication process combining physical deposition and inkjet-printing.

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“…In TaO Conversely, in bilayer memristors of TaO x and Ta, the lateral motion of oxygen vacancies or anions is thought to be key, with the oxygen concentration of a Ta rich conducting filament the purported state variable [83,86]. Quantitative models describing the physics of phenomena such as retention have been demonstrated [87], however, as summarized above, modeling of the physics of switching dynamics in TaOx memristors has been primarily qualitative. Here, we present a model based on microscopic ionic flux which quantitatively predicts the memristive operation of TaO x /Ta devices, providing close agreement with experimental resistive switching data.…”

Section: A Physical Model Of Switching Dynamics In Tantalum Oxide Memmentioning

confidence: 99%

A comprehensive approach to decipher biological computation to achieve next generation high-performance exascale computing.

James¹,

Schiess²,

Howell³

et al. 2013

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The human brain (volume=1200cm3) consumes 20W and is capable of performing > 10^16 operations/s. Current supercomputer technology has reached 1015 operations/s, yet it requires 1500m^3 and 3MW, giving the brain a 10^12 advantage in operations/s/W/cm^3. Thus, to reach exascale computation, two achievements are required: 1) improved understanding of computation in biological tissue, and 2) a paradigm shift towards neuromorphic computing where hardware circuits mimic properties of neural tissue. To address 1), we will interrogate corticostriatal networks in mouse brain tissue slices, specifically with regard to their frequency filtering capabilities as a function of input stimulus. To address 2), we will instantiate biological computing characteristics such as multi-bit storage into hardware devices with future computational and memory applications. Resistive memory devices will be modeled, designed, and fabricated in the MESA facility in consultation with our internal and external collaborators. (1463), and Robert Leland (1000) were crucial in helping to steer this effort in the larger context of Sandia's national security missions. We thank the Microelectronics Development Laboratory staff and management at Sandia National Laboratories for device fabrication. We also extend our gratitude to Michael Rye and Bonnie McKenzie for focused ion beam serial sectioning and scanning electron microscopy. We also thank our Hewlett Packard collaborators Byung Joon Choi, J. 4 ACKNOWLEDGMENTS

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Demonstration of high-density ReRAM ensuring 10-year retention at 85°C based on a newly developed reliability model

Cited by 108 publications

References 5 publications

Conduction Mechanism of Valence Change Resistive Switching Memory: A Survey

Conduction Mechanism of Valence Change Resistive Switching Memory: A Survey

Ge2Sb2Te5 layer used as solid electrolyte in conductive-bridge memory devices fabricated on flexible substrate

A comprehensive approach to decipher biological computation to achieve next generation high-performance exascale computing.

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