Nanoscale memristive devices using tungsten oxide as the switching layer have been fabricated and characterized. The devices show the characteristics of a flux-controlled memristor such that the conductance change is governed by the history of the applied voltage signals, leading to synaptic behaviors including long-term potentiation and depression. The memristive behavior is attributed to the migration of oxygen vacancies upon bias which modulates the interplay between Schottky barrier emission and tunneling at the WO X /electrode interface. A physical model incorporating ion drift and diffusion effects using an internal state variable representing the area of the conductive region has been proposed to explain the observed memristive behaviors. A SPICE model has been further developed that can be directly incorporated into existing circuit simulators. This type of device can be fabricated with low-temperature processes and has potential applications in synaptic computations and as analog circuit components.
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机译:已经制造并表征了使用氧化钨作为开关层的纳米级忆阻器件。这些设备显示了磁通量控制忆阻器的特性,因此电导率变化受施加的电压信号的历史控制,从而导致突触行为,包括长期的增强和抑制。忆阻行为归因于偏置时氧空位的迁移,从而调节了肖特基势垒发射与WO X /电极界面处的隧穿之间的相互作用。已经提出了使用代表导电区域面积的内部状态变量结合了离子漂移和扩散效应的物理模型来解释观察到的忆阻行为。进一步开发了SPICE模型,可以将其直接合并到现有的电路模拟器中。这种类型的设备可以用低温工艺制造,并且在突触计算和模拟电路组件中具有潜在的应用。
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