dc.description.abstract | In this thesis, after introducing some theoretical aspects of Mott insulators, pure
single crystals of the Mott insulator Ca2RuO4 was investigated from an experimental
point of view. The surprisingly low current density required to induce the insulator to
metal transition has made this material an attractive candidate for developing Mott based electronics devices. However, the mechanism driving the resistive switching
remains a controversial topic in the field of strongly correlated electron systems.
Here, electrical transport measurements combined with X-ray diffraction have been
performed to refine the crystallographic structural phases. A non-equilibrium state
which is the precursor of the fully metallic phase was found and adequately
characterised. Furthermore, electric transport measurements of the eutectic system
constituted by Ca2RuO4 with embedded metallic Ru inclusions have been performed.
In this system, the same properties of the pure Ca2RuO4 were found, although the Ru
inclusions make it structurally stiffer.
Moreover, using the sample size as a principal tuning parameter, an uncovered region
of the phase space of pure Ca2RuO4 single crystal has been probed. To decrease the
dimensions of the crystals down to the microscopic scale, an innovative technique
that involves a Ga+ focused ion beam has been employed. Upon reducing the crystal
size, an increase of four orders of magnitude in the current density is required for
driving Ca2RuO4 out of the insulating state into the non-equilibrium phase. This
effect was observed for the very first time. By fabricating a microscopic platinum
thermometer directly on top of selected samples and performing thermal simulations,
it was gained insight into the local temperature during simultaneous application of
current, and it was established that the observed “size effect” is not a result of Joule
heating. The findings suggest an inhomogeneous current distribution in the nominally
homogeneous crystal.
This study paves the way to a new approach to investigate the physical properties of
Mott insulators and calls for a re-examination of the interplay between sample size,
charge current, and temperature in driving Ca2RuO4 towards the insulator to metal
transition. [edited by Author] | it_IT |