On the behavior of a distributed network of capacitive constant phase elements

Abstract

As a generalization of integer-order calculus, fractional calculus has seen tremendous applications in the past few years especially in the description of anomalous viscoelastic properties, transport processes in complex media as well as in dielectric and impedance spectroscopy of materials and electrode/electrolyte interfaces. The fractional-order capacitor or constant phase element (CPE) is a fractional-order model with impedance zc(s) = 1/(Cα sα) (s=j ω, Cα>0, 0<α<1) and is widely used in modeling impedance spectroscopy data in dispersive materials. In this study, we investigate the behavior of a network of distributed-order CPEs, each of which described by a Caputo-type time fractional differential equation relating the current on the CPE to its voltage, but with a non-negative, time-invariant weight function φ(α). The behavior of the distributed-order network in terms of impedance and time-domain response to a constant current excitation is derived for two simple cases of φ(α): (i) φ(α)=1 for 0 < α < 1 and zero otherwise, and (ii) φ(α) = Σi Cαi\, δ(α-αi) corresponding to the general case of parallel-connected elemental CPEs of different orders α, and pseudocapacitances Cα. Our results show that the overall network is not equivalent to a single CPE, contrary to what would of been expected with ideal capacitors.

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