Quantum hall transformer in a quantum point contact over the full range of transmission

Abstract: A recent experiment [Cohen et al., Science 382, 542 (2023)] observed a quantized $e^2/2h$ conductance tunneling into a fractional quantum hall edge in the strong coupling limit, which is consistent with the prediction of a quantum Hall transformer. We model this quantum point contact (QPC) as a quantum wire with a spatially-varying Luttinger parameter and a back-scattering impurity and use a numerical solution to find the wavepacket scattering and microwave (i.e. finite frequency) has conductance at the interface. We then compare the microwave conductance to an analytic solution of a Luttinger liquid with an abruptly varying Luttinger parameter and a back-scattering impurity, which is obtained by mapping the problem to a boundary sine-Gordon (BSG) model. Finally, we show that the quantum Hall transformer can survive the inclusion of the domain wall which is expected to occur in a wide QPC, which is experimentally relevant, provided the momentum change in the QPC is generated by electrostatics. We find that back-scattering generated by the domain wall is of an order of magnitude consistent with the experiment.