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A steep-slope transistor based on abrupt electronic phase transition.


ABSTRACT: Collective interactions in functional materials can enable novel macroscopic properties like insulator-to-metal transitions. While implementing such materials into field-effect-transistor technology can potentially augment current state-of-the-art devices by providing unique routes to overcome their conventional limits, attempts to harness the insulator-to-metal transition for high-performance transistors have experienced little success. Here, we demonstrate a pathway for harnessing the abrupt resistivity transformation across the insulator-to-metal transition in vanadium dioxide (VO2), to design a hybrid-phase-transition field-effect transistor that exhibits gate controlled steep ('sub-kT/q') and reversible switching at room temperature. The transistor design, wherein VO2 is implemented in series with the field-effect transistor's source rather than into the channel, exploits negative differential resistance induced across the VO2 to create an internal amplifier that facilitates enhanced performance over a conventional field-effect transistor. Our approach enables low-voltage complementary n-type and p-type transistor operation as demonstrated here, and is applicable to other insulator-to-metal transition materials, offering tantalizing possibilities for energy-efficient logic and memory applications.

SUBMITTER: Shukla N 

PROVIDER: S-EPMC4918311 | biostudies-other | 2015

REPOSITORIES: biostudies-other

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A steep-slope transistor based on abrupt electronic phase transition.

Shukla Nikhil N   Thathachary Arun V AV   Agrawal Ashish A   Paik Hanjong H   Aziz Ahmedullah A   Schlom Darrell G DG   Gupta Sumeet Kumar SK   Engel-Herbert Roman R   Datta Suman S  

Nature communications 20150807


Collective interactions in functional materials can enable novel macroscopic properties like insulator-to-metal transitions. While implementing such materials into field-effect-transistor technology can potentially augment current state-of-the-art devices by providing unique routes to overcome their conventional limits, attempts to harness the insulator-to-metal transition for high-performance transistors have experienced little success. Here, we demonstrate a pathway for harnessing the abrupt r  ...[more]

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