📝 SummarXiv

Abstract

Potassium tungsten bronzes (K$_x$WO$_3$) are nonstoichiometric oxides in which alkali ions, i.e., K+, occupy one-dimensional tunnels of the hexagonal WO6 framework, enabling coupled ionic-lectronic transport. While their bulk and nanostructured forms have been studied extensively, controlled synthesis of single-crystalline mesoscale samples suitable for device fabrication has remained limited. Here, we report a solid-liquid-solid (SLS) growth strategy that yields high-quality K$_x$WO$_3$ nanobelts with thicknesses down to ~36 nm and lateral sizes exceeding 100 um. The crystals display sharp optical domains arising from local variations in potassium occupancy, as confirmed by spatially resolved Raman spectroscopy and electron diffraction. Under applied bias, these domains vanish irreversibly, consistent with lateral redistribution of K+ ions along the tunnels. Two-terminal devices fabricated from individual nanobelts exhibit reproducible bipolar switching with resistance ratios of 10-30, characteristic short-term and long-term plasticity under pulsed excitation, and switching energies of ~25 nJ. These results establish K$_x$WO$_3$ as a model tunnel-structured oxide for studying electric-field-driven alkali-ion migration, while also highlighting its potential for stable, analog resistive switching and iontronic memory applications.