Eliminating surface effects via employing nitrogen doping to significantly improve the stability and reliability of ZnO resistive memory

Lin

et al. 2015

Jpn. J. Appl. Phys.

A Cu/SiO 2 /Pt structure was fabricated to investigate its resistive switching characteristics. The application of DC voltages with different polarities allowed for the reversible manipulation of the structure's resistance. This resistive switching phenomenon is the result of the formation and rupture of Cu conducting filaments near the Cu/SiO 2 interface. However, significant switching dispersion occurred during successive switching cycles, which resulted in operational difficulties and switching failure. In this study, a voltage prestress was applied to the structure in an attempt to minimize the switching dispersion. A statistical technique was used to analyze the status of formation/rupture sites, and a schematic model is proposed to explain the reason for the dispersion improvement. It is suggested that the voltage prestress builds nonconnected filaments and reduces the number of sites of filament formation/rupture. This reduction in the number of sites leads to reduced switching dispersion.

Section: Introductionmentioning

confidence: 99%

Improvement of switching uniformity in Cu/SiO₂/Pt resistive memory achieved by voltage prestress

Lin

et al. 2015

Jpn. J. Appl. Phys.

“…However, a detailed switching mechanism is still lacking. Several studies [12][13][14] proposed the surface effect on the resistive switching behaviors, which indicated that oxygen or humidity may influence the redox reaction in the interface or resistive layer. Although a RRAM device has many promising advantages, the resistive switching behavior is unstable and may cause operation failure.…”

Section: Introductionmentioning

confidence: 99%

Resistive Switching Characteristics of a SiO_x Layer with CF₄ Plasma Treatment

Journal of Nanomaterials

Tsai

Fang

et al. 2014

A 20 nm SiO layer is deposited using radio-frequency sputtering to form the resistive switching layer of a Cu/SiO /Pt memory device. The SiO -based device demonstrates the resistive switching characteristics with an electrochemical reaction. CF 4 plasma treatment was used to modify the SiO layer and incorporate fluorine atoms into the SiO layer. The bombardment damage and fluorine incorporation caused the SiO film to form a stack-like structure. This reduced the operating voltage and improved switching dispersion. The fluorine repaired the Cu/SiO interface, thus increasing the barrier height of the Cu/SiO interface and the resistance of the high resistance state. A statistical analysis of the conducting filament formation was performed in order to evaluate the number of formation/rupture sites. The resistive switching of the CF 4 -treated sample had higher possibility to use the same filament sites; thus, the CF 4 -treated sample had stable resistive switching behavior.

Applied Physics Letters

“…4 Indeed, recent studies investigating the influence of ambiences conditions, 5 harsh environments, 6 and roughness 7 on metal oxidebased RRAM have highlighted SDR as the main cause of low switching yield and resistance fluctuation. On the other hand, the treatments such as surface modification, 6 doping, 8 and electrode material engineering 9 have improved RS stability and RRAM performance due to the better controllability of chemisorbed oxygen at surface-related defects. In this regard, the light illumination with the energy higher than the bandgap of metal oxide memory, which modulates the chemisorbed oxygen at surface-related defects via oxygen photodesorption 10 is expected to have impacts on RRAM stability and performance.…”

Section: Effect Of Ultraviolet Illumination On Metal Oxide Resistive mentioning

confidence: 99%

Effect of ultraviolet illumination on metal oxide resistive memory

Retamal

Kang

et al. 2014

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