Control of Mooij correlations at the nanoscale in the disordered metallic Ta-nanoisland FeNi multilayers.

Localisation phenomena in highly disordered metals close to the extreme conditions determined by the Mott-Ioffe-Regel (MIR) limit when the electron mean free path is approximately equal to the interatomic distance is a challenging problem. Here, to shed light on these localisation phenomena, we studied the dc transport and optical conductivity properties of nanoscaled multilayered films composed of disordered metallic Ta and magnetic FeNi nanoisland layers, where ferromagnetic FeNi nanoislands have giant magnetic moments of 10[Formula: see text]-10[Formula: see text] Bohr magnetons ([Formula: see text]). In these multilayered structures, FeNi nanoisland giant magnetic moments are interacting due to the indirect exchange forces acting via the Ta electron subsystem. We discovered that the localisation phenomena in the disordered Ta layer lead to a decrease in the Drude contribution of free charge carriers and the appearance of the low-energy electronic excitations in the 1-2 eV spectral range characteristic of electronic correlations, which may accompany the formation of electronic inhomogeneities. From the consistent results of the dc transport and optical studies we found that with an increase in the FeNi layer thickness across the percolation threshold evolution from the superferromagnetic to ferromagnetic behaviour within the FeNi layer leads to the delocalisation of Ta electrons from the associated localised electronic states. On the contrary, we discovered that when the FeNi layer is discontinuous and represented by randomly distributed superparamagnetic FeNi nanoislands, the Ta layer normalized dc conductivity falls down below the MIR limit by about 60%. The discovered effect leading to the dc conductivity fall below the MIR limit can be associated with non-ergodicity and purely quantum (many-body) localisation phenomena, which need to be challenged further.

Anomalous optical nonreciprocity in magnetic nanoisland arrays.

We study the phenomenon of optical nonreciprocity in multilayer systems of magnetic nanoislands [FeNi-Al2O3] N . An anomalously large optical nonreciprocity was observed in these systems. The effect was manifested in nonequivalence of polarization plane rotation of reflected light for the sample in an initial position and rotated by [Formula: see text]. We assume that the super-vortex magnetization in the FeNi layers is responsible for the optical nonreciprocity effect. It was found that the value of nonreciprocity effect depends on the effective thickness of FeNi island layer and reaches a maximum with the super-vortex magnetization formation. The nonreciprocity magnitude is significantly higher than the values observed recently in systems of specially formed magnetic nanoparticles. Nonreciprocity magnitude is strongly dependent on interlayer interaction between nanoisland layers at large distances.

[Microionophoretic study of interaction of cyclic purine nucleotides and mediator substances on the cortical neurons]. / Mikroionoforeticheskoe issledovanie vzaimodeistviia na neironakh kory mozga tsiklicheskikh purinovykh nukleotidov i mediatornykh veshchestv.

Statistically significant data indicating selective interaction of noradenaline and cAMP as well as of acetylcholine and cGMP were obtained in experiments on the microionophoretic bringing of cyclic purine nucleotides and mediator substances acetylcholine and noradrenaline to the rabbit cortical neurons. Studies on the relationships between cAMP and cGMP at the single unit level suggest their multilevel functional interaction with other systems of intracellular regulators.