Electronic thermal transport measurement in low-dimensional materials with graphene non-local noise thermometry

Waissman, Jonah; Anderson, Laurel E.; Talanov, Artem; Yan, Zhongying; Shin, Young Jae; Najafabadi, Danial Haei; Rezaee, Mehdi; Feng, Xiaowen; Nocera, Daniel G.; Taniguchi, Takashi; Watanabe, Kenji; Skinner, B. F.; Матвеев, К. А.; Kim, Philip

doi:10.1038/s41565-021-01015-x

Cited by 24 publications

(13 citation statements)

References 68 publications

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“…We highlight that high-resolution thermal imaging and scanning gate microscopes [40,41] and Johnson-Nyquist nonlocal noise thermometry [42,43] may provide exquisite tools to probe viscous electron vorticity in parameter domains where these signatures are no longer present in the charge transport mode.…”

Section: Discussionmentioning

confidence: 99%

Nonlocal thermoelectric resistance in vortical viscous transport

Li,

Levchenko

2022

Preprint

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The pursuit for clearly identifiable signatures of viscous electron flow in the solid state systems has been a paramount task in the search of the hydrodynamic electron transport behavior. In this work, we investigate theoretically the nonlocal electric and thermal resistances for the generic non-Galileaninvariant electron liquids in the multiterminal Hall-bar devices in the hydrodynamic regime. The role of the device inhomogeneity is carefully addressed in the model of the disorder potential with the long-range correlation radius. We obtain analytic expressions for the thermoelectric resistances that are applicable in the full crossover regime from charge neutrality to high electron density. We show that the vortical component of the electron flow manifests in the thermal transport mode close to the charge neutrality where vorticity is already suppressed by the intrinsic conductivity in the electric current. This behavior can be tested by the high-resolution thermal imaging probes.

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Section: Discussionmentioning

confidence: 99%

Nonlocal thermoelectric resistance in vortical viscous transport

Li,

Levchenko

2022

Preprint

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“…The results of this section can be tested by spaceresolving probes of hydrodynamic electron transport in graphene, e.g. in a measurement based on the nonlocal noise thermometry [48]. They are also relevant for experimental interpretation of macroscopic transport measurements in graphene Hall bars.…”

Section: Clean System With Nonuniform Densitymentioning

confidence: 99%

Hydrodynamic electron transport in graphene Hall-bar devices

Li,

Andreev,

Levchenko

2022

Preprint

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“…The first is the backscattering of plasmon modes at the edge-mode contact interface [S4, S7]. This term is length independent and proportional to the difference in temperatures squared, 𝑃 d→u 1 (𝑇 1 , 𝑇 2 , 𝑙) ∝ 𝑇 1 2 − 𝑇 2 2 . The exact coefficient depends on an exact theory of the edge modes.…”

Section: Thermal Hall Conductancementioning

confidence: 99%

“…), where 𝐼 is the impinging DC current, 𝑒 ⋆ the particles' charge and 𝜒(𝑥) = coth(𝑥) − 1 𝑥 . The excess power carried by the partitioned edge mode has two contributions: the trivial electrical power due to the transmitted direct current, 𝑃 DC = 1 2𝐺 2T (𝑡𝐼) 2 , and the power stored in current fluctuations at all frequencies,…”

mentioning

confidence: 99%

Direct Determination of the Topological Thermal Conductance via Local Power Measurement

Melcer

Konyzheva

Heiblum

et al. 2022

Preprint

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Thermal conductance measurements, sensitive to charge and chargeless energy flow, are evolving as an essential measurement technique in Condensed Matter Physics. For two-dimensional topological insulators, the measurements of the thermal Hall conductance, κxyT, and the longitudinal one κxxT, are crucial for the understanding of their underlying topological order. Such measurements are thus far lacking, even in the extensively studied quantum Hall effect (QHE) regime. Here, we report a new local power measurement technique that reveals the topological thermal Hall conductance (not the ubiquitous two-terminal one). For example, we find κxy~0 of the challenging ν = 2/3 particle-hole conjugated state. This is in contrast to the two-terminal measurement, which provides a non-universal value that depends on the extent of thermal equilibration between the counter-propagating edge modes. Moreover, we use this technique to study the power carried by the current fluctuations in a partitioned edge mode with an out-of-equilibrium distribution.

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Electronic thermal transport measurement in low-dimensional materials with graphene non-local noise thermometry

Cited by 24 publications

References 68 publications

Nonlocal thermoelectric resistance in vortical viscous transport

Nonlocal thermoelectric resistance in vortical viscous transport

Hydrodynamic electron transport in graphene Hall-bar devices

Direct Determination of the Topological Thermal Conductance via Local Power Measurement

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