Kinetic Inductance of Josephson Junction Arrays: Dynamic and Equilibrium Calculations

Abstract

We show analytically that the inverse kinetic inductance L-1 of an overdamped junction array at low frequencies is proportional to the admittance of an inhomogeneous equivalent impedance network. The ijth bond in this equivalent network has an inverse inductance Jij(θi0-θj0-Aij), where Jij is the Josephson coupling energy of the ijth bond, θi0 is the ground-state phase of the grain i, and Aij is the usual magnetic phase factor. We use this theorem to calculate L-1 for square arrays as large as 180× 180. The calculated L-1 is in very good agreement with the low-temperature limit of the helicity modulus γ calculated by conventional equilibrium Monte Carlo techniques. However, the finite temperature structure of γ, as a function of magnetic field, is sharper than the zero-temperature L-1, which shows surprisingly weak structure. In triangular arrays, the equilibrium calculation of γ yields a series of peaks at frustrations f = 12(1-1/N), where N is an integer ≥ 2, consistent with experiment.

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