Hanbury Brown-Twiss interferometry at the $ν=2/5$ fractional quantum Hall edge
Ryotaro Sano, Fumihiro Murabayashi, Daigo Ichikawa, Thibaut Jonckheere, Jérôme Rech + 3 more
TLDR
A new Hanbury Brown-Twiss interferometer for fractional quantum Hall edges reveals two-particle interference with fractional charge e/3.
Key contributions
- Proposes a Hanbury Brown-Twiss (HBT) interferometer for $ν=2/5$ fractional quantum Hall edge systems.
- Relies on two-particle interference, unlike previous single-particle anyonic interferometers.
- Predicts flux-dependent noise with fractional charge $e/3$ and FQH edge mode scaling dimensions.
- Shows anyonic exchange phases cancel in large devices but may reappear at thermal length scales.
Why it matters
This work introduces a novel approach to probe anyonic statistics in fractional quantum Hall systems using two-particle interference. It offers a distinct method from single-particle interferometers to directly observe fractional charge and the unique properties of FQH edge modes. This could advance our understanding of exotic quantum matter.
Original Abstract
We propose a Hanbury Brown-Twiss interferometer for a $ν=2/5$ fractional quantum Hall edge system, in which quasiparticles tunnel between two co-propagating edge modes. In contrast to the previously studied anyonic Fabry-Pérot and Mach-Zehnder interferometers, the proposed setup relies purely on two-particle interference rather than single-particle interference. In the weak-tunneling regime, we employ a bosonized edge theory together with Keldysh perturbation theory to evaluate the cross-correlation of the tunneling currents. In the large-device limit, we obtain an analytic expression for the flux-dependent noise, whose structure closely resembles that of an electronic HBT interferometer, but with the electron charge replaced by the fractional charge $e^{\star}=e/3$ and with scaling dimensions characteristic of the fractional edge modes. In this limit, the explicit anyonic exchange phases cancel, whereas when the device size becomes comparable to the thermal length, the cross-correlation may recover a more explicit dependence on the anyonic statistical angle.
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