English

Dynamical Coulomb blockade under a temperature bias

Mesoscale and Nanoscale Physics 2021-05-26 v1 Strongly Correlated Electrons Quantum Physics

Abstract

We observe and comprehend the dynamical Coulomb blockade suppression of the electrical conductance across an electronic quantum channel submitted to a temperature difference. A broadly tunable, spin-polarized Ga(Al)As quantum channel is connected on-chip, through a micron-scale metallic node, to a linear RCRC circuit. The latter is made up of the node's geometrical capacitance CC in parallel with an adjustable resistance R{1/2,1/3,1/4}×h/e2R\in \{1/2,1/3,1/4\}\times h/e^2 formed by 2--4 quantum Hall channels. The system is characterized by three temperatures: a temperature of the electrons in the large electrodes (TT) and in the node (TnodeT_\mathrm{node}), and a temperature of the electromagnetic modes of the RCRC circuit (TenvT_\mathrm{env}). The temperature in the node is selectively increased by local Joule dissipation, and characterized from current fluctuations. For a quantum channel in the tunnel regime, a close match is found between conductance measurements and tunnel dynamical Coulomb blockade theory. In the opposite near ballistic regime, we develop a theory that accounts for different electronic and electromagnetic bath temperatures, again in very good agreement with experimental data. Beyond these regimes, for an arbitrary quantum channel set in the far out-of-equilibrium situation where the temperature in the node significantly exceeds the one in the large electrodes, the equilibrium (uniform temperature) prediction for the conductance is recovered, albeit at a rescaled temperature αTnode\alpha T_\mathrm{node}.

Keywords

Cite

@article{arxiv.2104.03812,
  title  = {Dynamical Coulomb blockade under a temperature bias},
  author = {H. Duprez and F. Pierre and E. Sivre and A. Aassime and F. D. Parmentier and A. Cavanna and A. Ouerghi and U. Gennser and I. Safi and C. Mora and A. Anthore},
  journal= {arXiv preprint arXiv:2104.03812},
  year   = {2021}
}

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R2 v1 2026-06-24T00:58:02.739Z