Room Temperature Polymorphism in WO3 Produced by Resistive Heating of W Wires

Polymorphous WO3 micro- and nanostructures have been synthesized by the controlled Joule heating of tungsten wires under ambient conditions in a few seconds. The growth on the wire surface is assisted by the electromigration process and it is further enhanced by the application of an external electric field through a pair of biased parallel copper plates. In this case, a high amount of WO3 material is also deposited on the copper electrodes, consisting of a few cm(2) area. The temperature measurements of the W wire agrees with the values calculated by a finite element model, which has allowed us to establish the threshold density current to trigger the WO3 growth. The structural characterization of the produced microstructures accounts for the gamma-WO3 (monoclinic I), which is the common stable phase at room temperature, along with low temperature phases, known as delta-WO3 (triclinic) on structures formed on the wire surface and e-WO3 (monoclinic II) on material deposited on external electrodes. These phases allow for a high oxygen vacancies concentration, which is interesting in photocatalysis and sensing applications. The results could help to design experiments to produce oxide nanomaterials from other metal wires by this resistive heating method with scaling-up potential.

Automated summary

Polymorphous WO3 micro- and nanostructures were synthesized by joule heating of tungsten wires, assisted by an external electric field, resulting in the growth of WO3 on both wire surface and copper electrodes. The temperature measurements confirmed the calculated threshold density current required for WO3 growth. The structural characterization revealed the presence of gamma-WO3, delta-WO3, and e-WO3 phases, which offer high oxygen vacancy concentration for various applications. These findings can facilitate the production of oxide nanomaterials from other metal wires using the resistive heating method.