Electrode dependence of filament formation in HfO2 resistive-switching memory

Lin, Kuan Liang; Hou, Tuo Hung; Shieh, Jiann; Lin, Jun; Chou, Cheng Tung; Lee, Yao Jen

doi:10.1063/1.3567915

Cited by 280 publications

(163 citation statements)

References 24 publications

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“…Based on the phenomena described above, the resistive switching behaviors are agreement with conductive filament model very well. Generally speaking, there are metal CF 27,35-37 and oxygen vacancy CF [38][39][40] in the binary oxide dielectric such as HfO 2 film. Many studies have been reported that active electrodes such as Ag 4,41 and Cu [35][36][37] tends to migrate and form CF connecting with counter electrodes, playing an important role in resistive switching process.…”

Section: Resultsmentioning

confidence: 99%

Unipolar resistive switching with forming-free and self-rectifying effects in Cu/HfO2/n-Si devices

et al. 2016

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One of the most effective methods integrating self-rectifying RRAM is alleviating sneak current in crossbar architecture. In this work, to investigate RRAMs with excellent properties of self-rectifying effect, simple Cu/HfO2/n-Si tri-layer devices are fabricated and investigated through I − V characteristic measurement. The experimental results demonstrate that the device exhibits forming-free behavior and a remarkable rectifying effect in low resistance state (LRS) with rectification ratio of 104 at ±1 V, as well as considerable OFF/ON ratio (resistive switching window) of 104 at 1 V. The formation and annihilation of localized Cu conductive filament plays a key role in the resistive switching between low resistance state (LRS) and high resistance state (HRS). In addition, intrinsic rectifying effect in LRS attributes to the Schottky contact between Cu filament and n-Si electrode. Furthermore, satisfactory switching uniformity of cycles and devices is observed. As indicated by the results, Cu/HfO2/n-Si devices have a high potential for high-density storage practical application due to its excellent properties.

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Section: Resultsmentioning

confidence: 99%

Unipolar resistive switching with forming-free and self-rectifying effects in Cu/HfO2/n-Si devices

et al. 2016

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“…1c suggests that some grain boundaries may carry some hopping current at voltages smaller than the SET voltage; this is possible if the environment of O sites happens to be more uniform than average and barriers for conduction may be smaller; see below for more detailed analysis of hopping conduction). We note that the conductive channels are not true metallic filaments as often suggested [11,12]. The hopping current is turned on by a high voltage and the grain boundaries behave as true nanovaristors.…”

mentioning

confidence: 99%

2D Nanovaristors at Grain Boundaries Account for Memristive Switching in Polycrystalline BiFeO₃

Shen

Yin

Puzyrev

et al. 2015

Adv Elect Materials

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Memristive switching in polycrystalline materials is widely attributed to the formation and rupture of conducting filaments, believed to be mediated by oxygen‐vacancy redistribution. The underlying atomic‐scale processes are still unknown, however, which limits device modeling and design. Here, experimental data are combined with multiscale calculations to elucidate the entire atomic‐scale cycle in undoped polycrystalline BiFeO3. Conductive atomic force microscopy reveals that the grain boundaries behave like 2D nanovaristors, while on the return part of the cycle, the decreasing current is through the grains. Using density‐functional‐theory and Monte Carlo calculations, the atomic‐scale mechanism of the observed phenomena is deduced. Oxygen vacancies in nonequilibrium concentrations are initially distributed relatively uniformly, but they are swept into the grain boundaries by an increasing voltage. A critical voltage, the SET voltage, then eliminates the barrier for hopping conduction through vacancy energy levels in grain boundaries. On the return part of the cycle, the grain boundaries are again nonconductive, but the grains show nonzero conductivity by virtue of remote doping by oxygen vacancies. The RESET voltage amounts to a heat pulse that redistributes the vacancies. The realization that nanovaristors are at the heart of memristive switching in polycrystalline materials may open possibilities for novel devices and circuits.

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“…In electronics industry, hafnium oxide-based material is currently used as an excellent high-k gate dielectric [1] and oxygen-deficient hafnium oxide also received additional interest for resistive-switching memories [2]. As for other applications, even though the hardness of hafnia (HfO 2 ) is not that high for it to be considered as a superhard material [3], it still attracts attention as a potential candidate for hard oxide-based materials [4].…”

Section: Introductionmentioning

confidence: 99%

Pressure-induced novel compounds in the Hf-O system from first-principles calculations

Zhang

Oganov

et al. 2015

Phys. Rev. B

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Electrode dependence of filament formation in HfO2 resistive-switching memory

Cited by 280 publications

References 24 publications

Unipolar resistive switching with forming-free and self-rectifying effects in Cu/HfO2/n-Si devices

Unipolar resistive switching with forming-free and self-rectifying effects in Cu/HfO2/n-Si devices

2D Nanovaristors at Grain Boundaries Account for Memristive Switching in Polycrystalline BiFeO₃

Pressure-induced novel compounds in the Hf-O system from first-principles calculations

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Electrode dependence of filament formation in HfO2 resistive-switching memory

Cited by 280 publications

References 24 publications

Unipolar resistive switching with forming-free and self-rectifying effects in Cu/HfO2/n-Si devices

Unipolar resistive switching with forming-free and self-rectifying effects in Cu/HfO2/n-Si devices

2D Nanovaristors at Grain Boundaries Account for Memristive Switching in Polycrystalline BiFeO3

Pressure-induced novel compounds in the Hf-O system from first-principles calculations

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2D Nanovaristors at Grain Boundaries Account for Memristive Switching in Polycrystalline BiFeO₃