Dissipation and quantum noise in chiral circuitry

Dissipation and quantum noise in chiral circuitry

Physica E: Low-dimensional Systems and Nanostructures 121, 114117 (2020) We obtain an empirical relation between the zero temperature, zero frequency quantum noise ${\small{(}}S{\small{(}}\omega=0{\small{)}}{\small{)}}$ and the related power dissipation ${\small{(}}D{\small{)}}$ for chiral circuitry...

Full description

Saved in:
Bibliographic Details
Main Authors: Wadhawan, Disha, Das, Sourin
Format: Journal Article
Language:English
Published: 25-07-2020
Subjects:
Physics - Mesoscale and Nanoscale Physics
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Physica E: Low-dimensional Systems and Nanostructures 121, 114117 (2020) We obtain an empirical relation between the zero temperature, zero frequency quantum noise ${\small{(}}S{\small{(}}\omega=0{\small{)}}{\small{)}}$ and the related power dissipation ${\small{(}}D{\small{)}}$ for chiral circuitry. We consider the case of single quantum point contact (QPC) which induces inter-edge scattering of electrons among $"n"$ number of chiral edges of $\nu=1$ quantum Hall state. The ratio of total maximum power dissipation generated at the QPC ($D_{total}$) to the sum of auto-correlated noise generated in the chiral edge channels emanating out of the QPC region ($S_{total}$) is shown to be, $D_{total}/S_{total}{\small{(}}\omega=0{\small{)}} = V/{\small{}}4 e{\small{}}$ where $e$ is the electronic charge and $V$ is the voltage imposed on any one of the "$n$" incoming edge channels while keeping remaining "$n-1$" edge channels grounded. This implies that this ratio is universal except for a linear voltage bias dependence, i.e., it is independent of details of the scattering matrix ($S$-matrix) of the QPC region. Here the maximum power dissipation in each chiral edge is defined as the rate at which energy would be lost if the non-equilibrium distribution of electrons generated by the QPC region in each chiral edge is equilibrated to the corresponding zero temperature Fermi distribution. Further, for ${\cal Z}_n$ symmetric $S$-matrix, we show that the universal behaviour persists even when all the bias voltages imposed on the incoming edge channels are kept finite and distinct.
DOI:10.48550/arxiv.1811.07289