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Graphene-ferroelectric metadevices for nonvolatile memory and reconfigurable logic-gate operations.


ABSTRACT: Memory metamaterials are artificial media that sustain transformed electromagnetic properties without persistent external stimuli. Previous memory metamaterials were realized with phase-change materials, such as vanadium dioxide or chalcogenide glasses, which exhibit memory behaviour with respect to electrically/optically induced thermal stimuli. However, they require a thermally isolated environment for longer retention or strong optical pump for phase-change. Here we demonstrate electrically programmable nonvolatile memory metadevices realised by the hybridization of graphene, a ferroelectric and meta-atoms/meta-molecules, and extend the concept further to establish reconfigurable logic-gate metadevices. For a memory metadevice having a single electrical input, amplitude, phase and even the polarization multi-states were clearly distinguishable with a retention time of over 10 years at room temperature. Furthermore, logic-gate functionalities were demonstrated with reconfigurable logic-gate metadevices having two electrical inputs, with each connected to separate ferroelectric layers that act as the multi-level controller for the doping level of the sandwiched graphene layer.

SUBMITTER: Kim WY 

PROVIDER: S-EPMC4737808 | biostudies-other | 2016

REPOSITORIES: biostudies-other

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Graphene-ferroelectric metadevices for nonvolatile memory and reconfigurable logic-gate operations.

Kim Woo Young WY   Kim Hyeon-Don HD   Kim Teun-Teun TT   Park Hyun-Sung HS   Lee Kanghee K   Choi Hyun Joo HJ   Lee Seung Hoon SH   Son Jaehyeon J   Park Namkyoo N   Min Bumki B  

Nature communications 20160127


Memory metamaterials are artificial media that sustain transformed electromagnetic properties without persistent external stimuli. Previous memory metamaterials were realized with phase-change materials, such as vanadium dioxide or chalcogenide glasses, which exhibit memory behaviour with respect to electrically/optically induced thermal stimuli. However, they require a thermally isolated environment for longer retention or strong optical pump for phase-change. Here we demonstrate electrically p  ...[more]

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