We present an asymptotically exact solution of a paradigmatic non-Hermitian model: the disordered interacting fermionic Hatano-Nelson model, or equivalently, the non-Hermitian spin-1/2 XXZ model. We use a renormalization group method suited for disordered systems and show that non-Hermitian couplings are relevant perturbations to the Hermitian model, which ultimately leads to a quantum-to-classical crossover. The ground state of the model consists of a collection of strongly coupled pairs of spins of arbitrary size at random positions which, unlike the Hermitian case, do not form singlets, but a mixture of the singlet and the M=0 triplet state. As a result, the magnetic susceptibility in the x, y-directions becomes negative and diverges at a finite small temperature. Additionally, in sharp contrast to the (L) increase observed in disordered Hermitian chains, the entanglement entropy of a partition of size L saturates for large L, as the strongly coupled pairs become classical and stop contributing at large length scales.
Mattiello et al. (Fri,) studied this question.
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