Structural, optical, and electrical properties of proton intercalation H+/Na+ phases in nanostructured titanates induced by pH during hydrothermal synthesis

In search of a promising alternative to manufacture anodes for sodium-ion batteries, a study of the pH variation during hydrothermal synthesis of nanostructures of sodium titanate is presented. In particular, structural, optical and electrical properties of these materials are assessed when varying the pH for two different synthesis conditions. A mixture of phases was found, in agreement with (Na, H)2Ti3O7 center dot nH2O, and its cause is attributed to the proton(H+)/sodium(Na+) exchange and the intercalation of structural water. Also, changes in the morphology of the structural phases were observed, for example the phase with lower interlaminal distance appears to be nanorods, instead of nanotubes. The relative weight between phases and the direct band gap can be tuned by controlling synthesis conditions, in particular pH conditions. An enhancement of new processes in the electrical response and the suppression or enhancement of some defect due to the mixture of phase is also discussed. Additionally, the changes in electrical properties over a possible operation temperature range of a potential device, between -30 degrees C and 50 degrees C is reported. It was found that the changes in impedance in the proposed temperature range are of the order of 25 % of the modulus. This work shows how the final Na+ content in the sample alters its optical and electrical properties, which are determinant in its performance as an anode.

Automated summary

This study explores a promising alternative for manufacturing anodes for sodium-ion batteries and evaluates the properties of nanostructures of sodium titanate by examining the pH variation during hydrothermal synthesis. The experimental results show that the relative weight between phases and the direct band gap can be controlled by adjusting the pH conditions, leading to changes in the morphology of the structural phases. Additionally, the changes in electrical properties over a possible operation temperature range of a potential device are discussed.