Coulomb blockade and quantum tunnelling in the low-conductivity phase of granular metals

Abstract

We study the effects of Coulomb interaction and inter-grain quantum tunnelling in an array of metallic grains using the phase-functional approach for temperatures T well below the charging energy Ec of individual grains yet large compared to the level spacing in the grains. When the inter-grain tunnelling conductance g1, the conductivity σ in d dimensions decreases logarithmically with temperature (σ/σ01-12π gd(gEc/T)), while for g0, the conductivity shows simple activated behaviour (σ (-Ec/T)). We show, for bare tunnelling conductance g 1, that the parameter γ g(1-2/(gπ)(gEc/T)) determines the competition between charging and tunnelling effects. At low enough temperatures in the regime 1 γ 1/β Ec, a charge is shared among a finite number N=(Ec/T)/(π/2γ z) of grains, and we find a soft activation behaviour of the conductivity, σ z-1(-2(Ec/T)(π/2γ z)), where z is the effective coordination number of a grain.

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