后cmos逻辑器件中强相关双层石墨烯的性能特征

2010 Silicon Nanoelectronics Workshop Pub Date : 2010-06-13 DOI:10.1109/SNW.2010.5562544

B. Dellabetta, M. J. Gilbert

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引用次数: 4

摘要

双层石墨烯中的后cmos逻辑非常有前途，因为可以观察室温集体状态。我们提出了石墨烯双层的计算和激子超流动性的必要条件。在室温下，冷凝液所能支持的最大电流比低温值有所增加，并且我们可以在冷凝液电流和超过最大电流后流动的非相互作用准粒子电流之间实现大于3个数量级的负差分电阻。

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Performance characteristics of strongly correlated bilayer graphene for post-CMOS logic devices

Post-CMOS logic in bilayer graphene is very promising due to the possibility of observing room temperature collective states. We present calculations of graphene bilayers and the conditions necessary for excitonic superfluidity. At room temperature, the maximum current the condensate can support is increased over low temperature values and we can achieve negative differential resistances greater than 3 orders of magnitude between the condensate current and the non-interacting quasiparticle current which flows after exceeding the maximum current.

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