Responsive charge transport in wide-band-gap oxide films of nanostructured amorphous alkali-gallium-germanosilicate

The demand for new responsive materials is continuously growing in several areas as a result of approaching the physical limits of technologies, which now calls for a drastic change of strategy. Here, we report on memory responsive oxide-in-oxide nanostructured films obtained by radio-frequency sputtering of a 7.5Li(2)O-2.5Na(2)O-20Ga(2)O(3)-45GeO(2)-25SiO(2) (mol%) glass target produced by melt quenching. Atomic force microscopy and scanning electron microscopy show that as-deposited oxide layers exhibit native nanophase separation, with the occurrence of Ga-rich oxide nanostructures - about 15 nm thick and 100 nm in diameter - incorporated in oxide layers about 70 nm thick. Interestingly, despite the wide band gap (above 4 eV), the nanostructured oxide films reveal the formation of unconventional electric field dependent charge transport paths across the material. The frequency and temperature dependence of electric conductivity and dielectric function highlights n-type conduction sustained by charge percolation through the oxide layer. Importantly, the results demonstrate the occurrence of conductivity changes by more than an order of magnitude in a few volts, and trapped charge values up to 10(16) electrons per cm(3).