Abstract A type of quantum interference network for electromagnetic radiation sensing, based on quantum wires, is proposed. A format is composed of symmetric hexagonal nanowire loops. The relevant quantum interference properties are analyzed, showing that the influence phase functional for the current density depends on the final relative velocity of electrons. Furthermore, the time evolution of the connectivity for this network obeys a power law, which is related to the influence functional phase. The calculation shows that the ratio of random/determination preferential attachment can change the curve shape of connectivity distribution strongly, and allow the network to appear to scale-rich properties.