Condensed Matter > Mesoscale and Nanoscale Physics
[Submitted on 15 May 2024]
Title:Thermoelectric and viscous contributions to the hydrodynamic ratchet effect
View PDF HTML (experimental)Abstract:We study thermoelectric and viscous contributions to the ratchet effect, i.e. radiation-induced generation of the direct electric current, $J_{\rm rat},$ in asymmetric dual-grating gate structure without inversion center. Previously [E.Mönch et al, Phys. Rev. B {\bf 105}, 045404 (2022)], it was demonstrated that frequency dependence of the $J_{\rm rat}$ is essentially different within hydrodynamic (HD) and drift-diffusion (DD) regimes of the electron transport: $ J_{\rm rat}^{\rm HD} \propto 1/\omega^6 $ and $ J_{\rm rat}^{\rm DD} \propto 1/\omega^2 $ for $\omega \to \infty.$ Here we analyze previously neglected thermoelectric contribution and find that it yields high-frequency asymptotic $1/\omega^2$ even in the HD regime and can change sign of the response. Account of the finite viscosity of the electron liquid yields contribution which scales at high frequency as $1/\omega^4.$ We also find plasmonic resonances in the $J_{\rm rat},$ and demonstrate that asymmetry of the structure allows for excitation of the so-called directional travelling plasmons.
Submission history
From: Valentin Kachorovskii [view email][v1] Wed, 15 May 2024 19:13:16 UTC (395 KB)
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