Investigating the Temperature Effects on ZnO, TiO2, WO3 and HfO2 Based Resistive Random Access Memory (RRAM) Devices

In this paper, we report the effect of filament radius and filament resistivity on the ZnO, TiO2, WO3 and HfO2 based Resistive Random Access Memory (RRAM) devices. We resort to the thermal reaction model of RRAM for the present analysis. The results substantiate decrease in saturated temperature with increase in the radius and resistivity of filament for the investigated RRAM devices. Moreover, a sudden change in the saturated temperature at a lower value of filament radius and resistivity is observed as against the steady change at the medium and higher value of the filament radius and resistivity. Results confirm the dependence of saturated temperature on the filament size and resistivity in RRAM

Investigating the Temperature Effects on ZnO, TiO2, WO3 and HfO2 Based Resistive Random Access Memory (RRAM) Devices

In this paper, we report the effect of filament radius and filament resistivity on the ZnO, TiO2, WO3 and HfO2 based Resistive Random Access Memory (RRAM) devices. We resort to the thermal reaction model of RRAM for the present analysis. The results substantiate decrease in saturated temperature with increase in the radius and resistivity of filament for the investigated RRAM devices. Moreover, a sudden change in the saturated temperature at a lower value of filament radius and resistivity is observed as against the steady change at the medium and higher value of the filament radius and resistivity. Results confirm the dependence of saturated temperature on the filament size and resistivity in RRAM

Дослідження моделювання постійного, змінного та перехідного струмів кантілівера MEMS

Робота присвячена дослідженню моделювання постійного, змінного та перехідного струмів кантілівера MEMS. У роботі моделюється прямокутна система відкритого типу. У даному випадку ми змінювали довжину кантілівера MEMS (платиновий електрод) і вивчали його вплив у наступних випадках: i) вплив напруги на ємність і положення променю (аналіз постійного струму), ii) положення променю у часовій області, ємність і напруга (аналіз змінного струму) та iii) положення променю у часовій області, ємність і напруга (аналіз перехідних процесів). Результати показали, що довжина активного електрода кантілівера MEMS значно впливає на продуктивність MEMS. Крім того, напруга на кантілівері MEMS лінійно зростає з часом і виявилося, що вона не залежить від довжини електрода і діелектричних матеріалів, які використовувалися в розглянутій системі.The present reports deals with the DC, AC, and transient simulation study of MEMS cantilever. The open-ended rectangular system is simulated in the present investigation. In the present case, we have varied the length of MEMS cantilever (platinum electrode) and studied its effect on the following cases: i) the effect of voltage on the capacitance and beam position (DC analysis), ii) time domain beam position, capacitance, and voltage (AC analysis), and iii) time domain beam position, capacitance, and voltage (transient analysis). The results suggested that the length of an active electrode of MEMS cantilever significantly affects the MEMS performance. In addition, the voltage of MEMS cantilever linearly increases with respect to time and it was found to be independent of the electrode length and dielectric materials, which were used in the considered system

Superhydrophobic Leaf Mesh Decorated with SiO2 Nanoparticle-Polystyrene Nanocomposite for Oil-Water Separation

Here, we report a novel and simple approach to fabricate crater-like superhydrophobic leaf mesh for oil-water separation. Nanocomposite of SiO2 and polystyrene (SiO2-PS) deposited on a naturally dried Tectona grandis leaf mesh showed excellent superhydrophobic and superoleophilic properties. The obtained multifunctional leaf mesh exhibited fast separation of various oils like petrol, kerosene, diesel, coconut oil from oil-water mixtures with separation efficiency greater than 95%, which lasts for more than 18 separation cycles. The prepared material can be used efficiently for the oil-water mixture separation for any oil with absolute viscosity of less than 55 cP.Scopu