Polarons, free charge localisation and effective dielectric permittivity in oxides

TL;DR

This review discusses how various types of free charge localization in oxides, such as polarons and space charge effects, influence the dielectric properties and spectra of these materials, with implications for understanding giant permittivity.

Contribution

It provides a comprehensive overview of charge localization mechanisms in oxides and their impact on dielectric spectra, highlighting the role of polarons and interface effects in diverse compounds.

Findings

Polarons influence dielectric spectra in ferroelectrics.

Residual impurities cause low-temperature anomalies.

Space charge localization may explain giant permittivity.

Abstract

This review will deal with several types of free charge localisation in oxides and their consequences on the effective dielectric spectra of such materials. The first one is the polaronic localisation at the unit cell scale on residual impurities in ferroelectric networks. The second one is the collective localisation of free charge at macroscopic interfaces like surfaces, electrodes and grain boundaries in ceramics. Polarons have been observed in many oxide perovskites mostly when cations having several stable electronic configurations are present. In manganites, the density of such polarons is so high as to drive a net lattice of interacting polarons. On the other hand, in ferroelectric materials like BaTiO3 and LiNbO3, the density of polarons is usually very small but they can influence strongly the macroscopic conductivity. The contribution of such polarons to the dielectric spectra of ferroelectric materials is described. Even residual impurities as for example Iron can induce well defined anomalies at very low temperatures. This is mostly resulting from the interaction between localised polarons and the highly polarisable ferroelectric network in which they are embedded. The case of such residual polarons in SrTiO3 will be described in more details, emphasizing the quantum polaron state at liquid helium temperatures. Recently, several non-ferroelectric oxides have been shown to display giant effective dielectric permittivity. It is first shown that the frequency/temperature behaviour of such parameters is very similar in very different compounds (donor doped BaTiO3, CaCu3Ti4O12, LuFe2O4,Li doped NiO,...). This similarity calls for a common origin of the giant dielectric permittivity in these compounds. A space charge localisation at macroscopic interfaces can be the key for such extremely high dielectric permittivity.