Abstract
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 interactiondominated 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.
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 interactiondominated 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.
Original language | English |
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Journal | Nature Communications |
Early online date | 31 Oct 2018 |
DOIs | |
Publication status | Published - 2018 |
Research Beacons, Institutes and Platforms
- National Graphene Institute