Observation of gauge field induced non-Hermitian helical spin skin effects

Synthetic gauge fields and non-Hermitian skin effects are pivotal to topological phases and non-Hermitian physics, each recently attracting great interest across diverse research fields. Notably, realizing skin effects typically require nonreciprocal couplings or on-site gain and loss. Here, we theoretically and experimentally report that, under gauge fields, non-Hermitian systems with reciprocal couplings and without gain and loss, can nontrivially give rise to an unprecedented nonreciprocal skin effect, featuring helical spin-dependent skin accumulations, dubbed as the ``helical spin skin effect". Specifically, we construct a lattice model with reciprocal dissipative couplings and gauge fields, implemented in circuit metamaterials. Before introducing the gauge fields, this model exhibits localized spin edge modes and extended bulk modes, without skin effects. As the gauge field strength is applied from $0$ to $\pi$, we observe the emergence of two distinct spin skin effects and their transitions: the hybrid-order and second-order helical spin skin effects. Furthermore, we show that these effects can be harnessed to realize helical spin-dependent nonreciprocal transmissions. Our findings not only highlight gauge field induced and enriched non-Hermitian topology, but also brings spin-dependent helicity into skin effects and nonreciprocality.