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01915 am a22002653u 4500 |
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124320 |
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|a dc
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|a Bandurin, Denis A.
|e author
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|a Massachusetts Institute of Technology. Department of Physics
|e contributor
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|a Shytov, Andrey V.
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|a Levitov, Leonid
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|a Kumar, Roshan Krishna
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|a Berdyugin, Alexey I.
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|a Ben Shalom, Moshe
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|a Grigorieva, Irina V.
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|a Geim, Andre K.
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|a Falkovich, Gregory
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|a Fluidity onset in graphene
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|b Springer Nature,
|c 2020-03-25T15:42:03Z.
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|z Get fulltext
|u https://hdl.handle.net/1721.1/124320
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|a Viscous electron fluids have emerged recently as a new paradigm of strongly-correlated electron transport in solids. Here we report on a direct observation of the transition to this long-sought-for state of matter in a high-mobility electron system in graphene. Unexpectedly, the electron flow is found to be interaction-dominated but non-hydrodynamic (quasiballistic) in a wide temperature range, showing signatures of viscous flows only at relatively high temperatures. The transition between the two regimes is characterized by a sharp maximum of negative resistance, probed in proximity to the current injector. The resistance decreases as the system goes deeper into the hydrodynamic regime. In a perfect darkness-before-daybreak manner, the interaction-dominated negative response is strongest at the transition to the quasiballistic regime. Our work provides the first demonstration of how the viscous fluid behavior emerges in an interacting electron system.
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|a Center for Integrated Quantum Materials (CIQM) (NSF award DMR-1231319)
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|a United States. Army Research Office (Grant W911NF-18-1-0116)
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|a Article
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|t Nature Communications
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