TY - JOUR

T1 - Slip Electron Flow in GaAs Microscale Constrictions

AU - Sarypov, Daniil I.

AU - Pokhabov, Dmitriy A.

AU - Pogosov, Arthur G.

AU - Zhdanov, Evgeny Yu.

AU - Shevyrin, Andrey A.

AU - Shklyaev, Alexander A.

AU - Bakarov, Askhat K.

N1 - The study was funded by the Russian Science Foundation (Grant No. 22-12-00343-П). The nanolithography was performed on the equipment of CKP “VTAN” in ATRC department of NSU. Sarypov, D. I. , Pokhabov, D. A., Pogosov, A. G., Zhdanov, E. Yu., Shevyrin, A. A., Shklyaev, A. A., Bakarov, A. K. Slip electron flow in GaAs microscale constrictions // Physical Review Letters. - 2025. - Т. 135. - № 23. - 236301. https://doi.org/10.1103/r8hl-91rv

PY - 2025/12/5

Y1 - 2025/12/5

N2 - Hydrodynamic electron transport in solids, governed by momentum-conserving electron-electron collisions, offers a unique framework to explore collective phenomena. Within this framework, correlated electron motion is modeled as viscous fluid flow, with viscosity serving as the interaction parameter. Advances in electron hydrodynamics remain constrained by two unresolved issues: the questionable existence of materials with intrinsically smooth boundaries enabling perfect slip in electron fluids and the lack of quantitative experimental confirmation of the theoretical relation linking the viscosity to electron-electron scattering length. Here, we resolve this through measurements of these quantities in the same electron system in GaAs/AlGaAs heterostructure. Our experiments reveal large flow slippage at boundaries of microscale constrictions—an unexpected phenomenon for electron liquid that parallels ultrafast water transport in carbon nanotubes. These findings bridge the fields of electron hydrodynamics and nanofluidics, highlighting the transformative potential of hydrodynamic engineering across condensed matter and fluidic technologies.

AB - Hydrodynamic electron transport in solids, governed by momentum-conserving electron-electron collisions, offers a unique framework to explore collective phenomena. Within this framework, correlated electron motion is modeled as viscous fluid flow, with viscosity serving as the interaction parameter. Advances in electron hydrodynamics remain constrained by two unresolved issues: the questionable existence of materials with intrinsically smooth boundaries enabling perfect slip in electron fluids and the lack of quantitative experimental confirmation of the theoretical relation linking the viscosity to electron-electron scattering length. Here, we resolve this through measurements of these quantities in the same electron system in GaAs/AlGaAs heterostructure. Our experiments reveal large flow slippage at boundaries of microscale constrictions—an unexpected phenomenon for electron liquid that parallels ultrafast water transport in carbon nanotubes. These findings bridge the fields of electron hydrodynamics and nanofluidics, highlighting the transformative potential of hydrodynamic engineering across condensed matter and fluidic technologies.

UR - http://arxiv.org/abs/2506.10276

UR - https://www.mendeley.com/catalogue/b30fae09-8c72-37fe-a58a-b4db7dd6c99f/

UR - https://www.scopus.com/pages/publications/105024197856

U2 - 10.1103/r8hl-91rv

DO - 10.1103/r8hl-91rv

M3 - Article

VL - 135

JO - Physical Review Letters

JF - Physical Review Letters

SN - 0031-9007

IS - 23

M1 - 236301

ER -