The role of nitrogen doping in ALD Ta2O5 and its influence on multilevel cell switching in RRAM

Sedghi, Naser; Li, Hongfei; Brunell, I.F.; Dawson, Karl; Potter, Richard J.; Guo, Yuzheng; Gibbon, James T.; Dhanak, V.R.; Zhang, W-D.; Jf, Zhang; Robertson, John; Hall, Steve; Chalker, Paul R.

doi:10.1063/1.4978033

Cited by 56 publications

(30 citation statements)

References 23 publications

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“…2(a). The I-V characteristics during the voltage sweeps are indicative of typical bipolar resistive switching behavior [15][16][17][18][19][20] . After the electroforming process, DC voltage sweeping from 0 V → 1 V → 0 V with an I CC of 1 mA resulted in a SET process (i.e., an off-to-on transition) and sweeping from 0 V → −0.7 V → 0 V without an I CC led to a RESET process (i.e., an on-to-off transition).…”

Section: Resultsmentioning

confidence: 99%

“…This type of multilevel resistance allows the possibility of multilevel storage, which can provide more storage space within a single cell and generate synaptic behavior, leading to material and structural innovation [11][12][13][14] . Thus, researchers have made an effort to realize multilevel storage using a variety of approaches, including heterostructures 15,16 , the insertion of an interlayer 17,18 , and doping techniques 19,20 .…”

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confidence: 99%

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Sputtering-deposited amorphous SrVOx-based memristor for use in neuromorphic computing

Lee

Kim

Seong

2020

Sci Rep

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The development of brain-inspired neuromorphic computing, including artificial intelligence (AI) and machine learning, is of considerable importance because of the rapid growth in hardware and software capacities, which allows for the efficient handling of big data. Devices for neuromorphic computing must satisfy basic requirements such as multilevel states, high operating speeds, low energy consumption, and sufficient endurance, retention and linearity. In this study, inorganic perovskite-type amorphous strontium vanadate (a-SrVO x : a-SVO) synthesized at room temperature is utilized to produce a high-performance memristor that demonstrates nonvolatile multilevel resistive switching and synaptic characteristics. Analysis of the electrical characteristics indicates that the a-SVO memristor illustrates typical bipolar resistive switching behavior. Multilevel resistance states are also observed in the off-to-on and on-to-off transition processes. The retention resistance of the a-SVO memristor is shown to not significantly change for a period of 2 × 10 4 s. The conduction mechanism operating within the Ag/a-SVO/Pt memristor is ascribed to the formation of Ag-based filaments. Nonlinear neural network simulations are also conducted to evaluate the synaptic behavior. These results demonstrate that a-SVo-based memristors hold great promise for use in high-performance neuromorphic computing devices. open Scientific RepoRtS | (2020) 10:5761 | https://doi.

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Sputtering-deposited amorphous SrVOx-based memristor for use in neuromorphic computing

Lee

Kim

Seong

2020

Sci Rep

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“…The MLC characteristics in 1R configuration can be obtained by changing the current compliance (I cc ) during 'set' operation whereas the MLC characteristics in 1-Transistor 1-RRAM (1T-1R) cell structure are controlled by varying the voltage at the gate of the transistor, which enables the control of compliance current (I cc ) during the set operation of a RRAM cell. The typical MLC I-V curves of Ti/Ta 2 O 5 /Pt [127] based RRAM cell are shown in Fig. 11.…”

Section: Mlc By Changing Compliance Currentmentioning

confidence: 99%

“…Multilevel characteristics of Ti/Ta 2 O 5 /Pt RRAM obtained by controlling the compliance current. 'Reproduced from[127], with the permission of AIP Publishing'…”

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confidence: 99%

Resistive Random Access Memory (RRAM): an Overview of Materials, Switching Mechanism, Performance, Multilevel Cell (mlc) Storage, Modeling, and Applications

2020

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In this manuscript, recent progress in the area of resistive random access memory (RRAM) technology which is considered one of the most standout emerging memory technologies owing to its high speed, low cost, enhanced storage density, potential applications in various fields, and excellent scalability is comprehensively reviewed. First, a brief overview of the field of emerging memory technologies is provided. The material properties, resistance switching mechanism, and electrical characteristics of RRAM are discussed. Also, various issues such as endurance, retention, uniformity, and the effect of operating temperature and random telegraph noise (RTN) are elaborated. A discussion on multilevel cell (MLC) storage capability of RRAM, which is attractive for achieving increased storage density and low cost is presented. Different operation schemes to achieve reliable MLC operation along with their physical mechanisms have been provided. In addition, an elaborate description of switching methodologies and current voltage relationships for various popular RRAM models is covered in this work. The prospective applications of RRAM to various fields such as security, neuromorphic computing, and non-volatile logic systems are addressed briefly. The present review article concludes with the discussion on the challenges and future prospects of the RRAM.

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“…esistive switching memory is a promising emerging non-volatile memory [1][2][3][4][5][6][7][8]. Good characteristics have been achieved in various binary metal-oxide based devices (RRAM), such as NiO [2], TiO2 [3,4], HfO2 [5,6], and Ta2O5 [7,8].…”

Section: Introductionmentioning

confidence: 99%

TDDB Mechanism in a-Si/TiO₂ Nonfilamentary RRAM Device

Chai

Zhang

et al. 2019

IEEE Trans. Electron Devices

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Mechanisms of time-dependent-dielectric-breakdown (TDDB) in non-filamentary a-Si/TiO2 RRAM cell (a-VMCO) have been examined in this work, including defects generation in the grain boundary, defects clustering and different defects generation rates in a-Si and TiO2 layers. The unique feature of a bimodal Weibull distribution at low resistance state (LRS) and a single shallow slope distribution at high resistance state (HRS) cannot be explained by the above mechanisms. By using a combination of constant-voltage-stress (CVS), time-to-breakdown Weibull distribution and random-telegraph-noise (RTN) based defect profiling in devices of various sizes, layer thickness and processes, it is revealed that the defect profile is modulated when switching between HRS and LRS and the correlation of defect profile modulation with local defect generation rate can explain the difference in Weibull distributions at HRS and LRS. The transition from bimodal distribution at LRS to a single-steepslope with thinner a-Si layer, and the good area scaling of Weibull distribution at HRS but not at LRS, can also be explained. The critical layers affecting the TDDB in a-VMCO are identified, providing useful guidance for device performance improvement.

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The role of nitrogen doping in ALD Ta2O5 and its influence on multilevel cell switching in RRAM

Cited by 56 publications

References 23 publications

Sputtering-deposited amorphous SrVOx-based memristor for use in neuromorphic computing

Sputtering-deposited amorphous SrVOx-based memristor for use in neuromorphic computing

Resistive Random Access Memory (RRAM): an Overview of Materials, Switching Mechanism, Performance, Multilevel Cell (mlc) Storage, Modeling, and Applications

TDDB Mechanism in a-Si/TiO₂ Nonfilamentary RRAM Device

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The role of nitrogen doping in ALD Ta2O5 and its influence on multilevel cell switching in RRAM

Cited by 56 publications

References 23 publications

Sputtering-deposited amorphous SrVOx-based memristor for use in neuromorphic computing

Sputtering-deposited amorphous SrVOx-based memristor for use in neuromorphic computing

Resistive Random Access Memory (RRAM): an Overview of Materials, Switching Mechanism, Performance, Multilevel Cell (mlc) Storage, Modeling, and Applications

TDDB Mechanism in a-Si/TiO2 Nonfilamentary RRAM Device

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TDDB Mechanism in a-Si/TiO₂ Nonfilamentary RRAM Device