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We consider quantum transport on a tight-binding model on the Bethe lattice of a finite generation, or the Cayley tree, which may model the energy transport in a light-harvesting molecule. As a new feature to analyze the quantum transport, we add complex potentials for sources on the peripheral sites and for a drain on the central site. We find that the eigenstates that can penetrate from the peripheral sites to the central site are quite limited to the number of generation. All the other eigenstates are localized around the peripheral sites and cannot reach the central site. The former eigenstates can carry the current, which reduces the problem to the quantum transport on a parity-time (PT) -symmetric tight-binding chain. When the number of links is common to all generations, the current takes the maximum value at the exceptional point for the zero-energy states, which emerges because of the non-Hermiticity due to the PT-symmetric complex potentials. As we introduce randomness in the number of links in each generation of the tree, the resulting linear chain is a random-hopping tight-binding model. We find that the current reaches its maximum not exactly but approximately for a zero-energy state, although it is no longer located at an exceptional point in general.
Hatano et al. (Tue,) studied this question.