Asymmetrically directed couplings in non-Hermitian systems cause directional amplification that leads to boundary skin state accumulation. However, counter-intuitively, the direction of accumulation may not follow that of the directed couplings. In this work, we demonstrate mechanisms where this accumulation can be systematically reversed without modifying the couplings at all, just by adjusting the system size or boundary conditions in a different, transverse direction. Moreover, the reversed skin dynamics can be made very robust by suppressing the amplification in the original non-reversed direction. We motivate our approach through a series of warm-up models, culminating in a designed non-Hermitian Kagome lattice, whereby wavepacket simulations demonstrate how robust reversed skin dynamics can be switched on/off in a non-local transverse manner. Our findings highlight how the non-trivial entanglement between the spectral loops of different PBC directions can be harnessed as a directional amplification switch, paving the way for avenues of non-Hermitian sensing and lasing. Asymmetric couplings in non-Hermitian systems typically result in the accumulation of so-called “skin” modes in the direction of the pumping. The authors show that this edge accumulation can be reversed or even switched on/off by non-locally tuning a transverse boundary, offering a simple route to reconfigurable amplification and sensing.
Yang et al. (Fri,) studied this question.