The current fluctuations due to a temperature bias, i.e., the delta-T noise, allow one to access properties of strongly interacting systems which cannot be addressed by the usual voltage-induced noise. In this work, we study the full delta-T noise between two different fractional quantum Hall edge states, with filling factors (νL, νR) in the Laughlin sequence, coupled through a quantum point contact and connected to two reservoirs at different temperatures. We are able to solve exactly the problem for all couplings and for any set of temperatures in the specific case of a hybrid junction (1/3, 1). Moreover, we derive a universal analytical expression which connects the delta-T noise to the equilibrium one valid for all generic pairs (νL, νR) up to the first order in the temperature mismatch. We expect that this linear term can be accessible in today’s experimental setups. We describe the two opposite-coupling regimes focusing on the strong one, which corresponds to a nontrivial situation. Our analysis on delta-T noise allows us to better understand the transport properties of strongly interacting systems and to move toward more involved investigations concerning the statistics and scaling dimension of their emergent excitations
Delta- T noise for fractional quantum Hall states at different filling factor
Giacomo Rebora;Dario Ferraro;Thierry Martin;Maura Sassetti
2022-01-01
Abstract
The current fluctuations due to a temperature bias, i.e., the delta-T noise, allow one to access properties of strongly interacting systems which cannot be addressed by the usual voltage-induced noise. In this work, we study the full delta-T noise between two different fractional quantum Hall edge states, with filling factors (νL, νR) in the Laughlin sequence, coupled through a quantum point contact and connected to two reservoirs at different temperatures. We are able to solve exactly the problem for all couplings and for any set of temperatures in the specific case of a hybrid junction (1/3, 1). Moreover, we derive a universal analytical expression which connects the delta-T noise to the equilibrium one valid for all generic pairs (νL, νR) up to the first order in the temperature mismatch. We expect that this linear term can be accessible in today’s experimental setups. We describe the two opposite-coupling regimes focusing on the strong one, which corresponds to a nontrivial situation. Our analysis on delta-T noise allows us to better understand the transport properties of strongly interacting systems and to move toward more involved investigations concerning the statistics and scaling dimension of their emergent excitationsI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.