Uncovering Two Competing Switching Mechanisms for Epitaxial and Ultrathin Strontium Titanate-Based Resistive Switching Bits

Kubicek, Markus; Schmitt, Rafael; Messerschmitt, Felix; Rupp, Jennifer L. M.

doi:10.1021/acsnano.5b02752

Cited by 78 publications

(55 citation statements)

References 56 publications

(122 reference statements)

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“…This large electric field produces nonlinear drifting of vacancies near the boundary interfaces, which further results in high nonlinearity in the I-V characteristics. The increase in the loop area with an increase in the bias is in good agreement with the experimental result reported in the literature for different active layer materials and device structures [24,25].…”

Section: Effect Of Write Voltage and Frequency On Memristor-based Rramsupporting

confidence: 91%

Effect of write voltage and frequency on the reliability aspects of memristor-based RRAM

et al. 2017

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In this paper, we report the effect of the write voltage and frequency on memristor-based resistive random access memory (RRAM). The above-said parameters have been investigated on the linear drift model of the memristor. With a variation of write voltage from 0.2 to 1.2 V and a subsequent frequency modulation from 1, 2, 4, 10, 100 and 200 Hz, the corresponding effects on memory window, low resistance state (LRS) and high resistance state (HRS) have been reported. Thus, the lifetime (s) reliability analysis of memristor-based RRAM is carried out using the above results. It is found that the HRS is independent of the write voltage, whereas LRS shows dependency on write voltage and frequency. The simulation results showcase the fact that the memristor possesses higher memory window and lifetime (s) in the higher voltage with lower frequency region, which has been attributed to less data losses in the memory architecture.

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Section: Effect Of Write Voltage and Frequency On Memristor-based Rramsupporting

confidence: 91%

Effect of write voltage and frequency on the reliability aspects of memristor-based RRAM

et al. 2017

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“…Electronic synapses are regarded as the physical building block for a hardware based artificial neural network with the function of brain-like computing 2 . Quite encouragingly, memristive devices 3–6 have been reported to efficiently emulate several neuromorphic and cognitive properties, such as all-or-nothing spiking of an action potential in neuristors 7 , synaptic plasticity (e.g. spike-timing-dependent plasticity (STDP) and metaplasticity) 8–16 , pattern learning 17, 18 and Pavlovian conditioning 19–27 .…”

Section: Introductionmentioning

confidence: 99%

Pavlovian conditioning demonstrated with neuromorphic memristive devices

Tan

Yin

Yang

et al. 2017

Sci Rep

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Pavlovian conditioning, a classical case of associative learning in a biological brain, is demonstrated using the Ni/Nb-SrTiO3/Ti memristive device with intrinsic forgetting properties in the framework of the asymmetric spike-timing-dependent plasticity of synapses. Three basic features of the Pavlovian conditioning, namely, acquisition, extinction and recovery, are implemented in detail. The effects of the temporal relation between conditioned and unconditioned stimuli as well as the time interval between individual training trials on the Pavlovian conditioning are investigated. The resulting change of the response strength, the number of training trials necessary for acquisition and the number of extinction trials are illustrated. This work clearly demonstrates the hardware implementation of the brain function of the associative learning.

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“…[20,21] Resistive switching devices were demonstrated on donor (i.e., Nb) doped, [22][23][24] acceptor (i.e., Fe) doped [25,26] and nominally undoped SrTiO 3 . [19,[27][28][29] Nb is a shallow donor dopant that creates a strong n-type conductivity with a very low concentration of oxygen vacancies [30] while Fe forms an acceptor level in the SrTiO 3 band gap. [31] In Fe doped SrTiO 3 oxygen vacancies were suggested to be responsible for the resistive switching [25] while in Nb doped SrTiO 3 it was both reoxidation through the top Pt electrode [23] and electronic charge trapping at the metal-oxide interface.…”

Section: Introductionmentioning

confidence: 99%

“…[22] The switching polarity has been consistently different with both dopants, Nb exhibiting eightwise polarity [22,23] and Fe counter-eightwise or both competing polarities. [25,29,32,33] Competing switching polarities dependent on the electrical field are possible in a single switching bit [25,29] and a debate in the literature has been ongoing about the switching mechanism in devices with the eightwise polarity. [19,34] Recently, Cooper et al proposed oxygen evolution and reincorporation into the high work function platinum electrode as the mechanism in undoped SrTiO 3 .…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Eightwise Switching Mechanism and Its Suppression in SrTiO₃ Modulated by Humidity and Interchanged Top and Bottom Platinum and LaNiO₃ Electrode Contacts

Sediva

Bowman

Gonzalez‐Rosillo

et al. 2018

Adv Elect Materials

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Memristive devices are hardware components for applications in neuromorphic computing, memories, and logic computation. This work contributes to the ongoing debate on the switching mechanism of eightwise polarity in SrTiO3‐based resistive switches. Specifically the effect of atmospheric humidity on the materials defect chemistry and switching properties is considered. Asymmetric devices are designed by exchanging the top and bottom positions of Pt and LaNiO3 electrodes allowing for a separate analysis of the top and the bottom metal‐oxide interfaces. Under dry atmospheres the switching hysteresis is enhanced with a top Pt contact and suppressed with a bottom Pt contact. It is argued that the buried position and dense microstructure of the bottom platinum impedes an oxygen vacancy driven switching mechanism. Under humid atmospheres eightwise switching occurs in both devices suggesting the presence of two switching mechanisms within the same eightwise switching polarity, namely, oxygen vacancy and hydroxide ion enabled switching. The findings help develop strategies to suppress eightwise switching by burying the active metal‐oxide interface and ensuring dense electrode microstructures. Suppression of switching mechanisms relying on exchange with the environment is desirable for technological implementation of resistive switches and for strategies in stacking of memristive devices for memory and for neuromorphic hardware.

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Uncovering Two Competing Switching Mechanisms for Epitaxial and Ultrathin Strontium Titanate-Based Resistive Switching Bits

Cited by 78 publications

References 56 publications

Effect of write voltage and frequency on the reliability aspects of memristor-based RRAM

Effect of write voltage and frequency on the reliability aspects of memristor-based RRAM

Pavlovian conditioning demonstrated with neuromorphic memristive devices

Investigation of the Eightwise Switching Mechanism and Its Suppression in SrTiO₃ Modulated by Humidity and Interchanged Top and Bottom Platinum and LaNiO₃ Electrode Contacts

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Uncovering Two Competing Switching Mechanisms for Epitaxial and Ultrathin Strontium Titanate-Based Resistive Switching Bits

Cited by 78 publications

References 56 publications

Effect of write voltage and frequency on the reliability aspects of memristor-based RRAM

Effect of write voltage and frequency on the reliability aspects of memristor-based RRAM

Pavlovian conditioning demonstrated with neuromorphic memristive devices

Investigation of the Eightwise Switching Mechanism and Its Suppression in SrTiO3 Modulated by Humidity and Interchanged Top and Bottom Platinum and LaNiO3 Electrode Contacts

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Investigation of the Eightwise Switching Mechanism and Its Suppression in SrTiO₃ Modulated by Humidity and Interchanged Top and Bottom Platinum and LaNiO₃ Electrode Contacts