Resistive switching can be achieved in a Mott insulator by applying current/voltage, which triggers an insulator-metal transition (IMT). This phenomenon is key for understanding IMT physics and developing novel memory elements and brain-inspired technology. Despite this, the roles of electric field and Joule heating in the switching process remain controversial. Using nanowires of two archetypal Mott insulators-VO 2 and V 2 O 3 we unequivocally show that a purely non-thermal electrical IMT can occur in both materials. The mechanism behind this effect is identified as field-assisted carrier generation leading to a doping driven IMT. This effect can be controlled by similar means in both VO 2 and V 2 O 3 , suggesting that the proposed mechanism is generally applicable to Mott insulators. The energy consumption associated with the non-thermal IMT is extremely low, rivaling that of state-of-the-art electronics and biological neurons. These findings pave the way towards highly energy-efficient applications of Mott insulators.
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机译:通过施加电流/电压,可以通过施加绝缘体 - 金属转换(IMT)来在薄膜绝缘体中实现电阻切换。这种现象是了解IMT物理和开发新型记忆元件和脑启发技术的关键。尽管如此,电场和焦耳加热在开关过程中的作用保持争议。使用两个archetypal Mott Insululators-Vo 2和V 2 O 3的纳米线我们明确表明,两种材料中可以发生纯粹的非热电IMT。这种效果背后的机制被识别为现场辅助的载体生成,导致掺杂驱动的IMT。这种效果可以通过VO 2和V 2 O 3中的类似手段来控制,表明所提出的机制通常适用于Mott绝缘体。与非热IMT相关的能量消耗极低,竞争最先进的电子和生物神经元。这些调查结果为Mott Insulator的高度节能应用铺平了途径。
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