Localized waves in silicates. What do we know from experiments?

TL;DR

This paper reviews experimental findings on localized waves, called quodons, in silicates, confirming their role in charge transport and hyperconductivity, and discusses numerical simulations and alternative explanations.

Contribution

It provides a comprehensive review of experimental results on quodons in silicates, including new data and insights into charge transport mechanisms.

Findings

Confirmation of charge transport by quodons in silicates

Observation of hyperconductivity without electric field

Numerical simulations supporting quodons energy estimates

Abstract

Since the latest review about solitary localized waves in muscovite, called quodons, [FM Russell, Springer Ser. Mater Sci. 221 (2015) 3] there have been many developments, specially from the point of view of experiments, published in several journals. The breakthrough hypothesis that was advanced in that review that dark tracks were produced by positive electrical charge moving in a localized wave, either transported by swift particles or by nonlinear localized waves, has been confirmed by experiments in muscovite and other silicates. In this paper we review the experimental results, some already published and some new, specially the phenomenon of charge transport without an electric field, called hyperconductivity. We also consider alternative explanations as phase transitions for other tracks. We also attempt to describe numerical simulations that have confirmed the order of magnitude of quodons energy and calculations underway to determine more properties of electron and hole transport by quodons