W <sub>18</sub> O <sub>49</sub> Nanowhiskers Decorating SiO <sub>2</sub> Nanofibers: Lessons from <i>In Situ</i> SEM/TEM Growth to Large Scale Synthesis and Fundamental Structural Understanding
Vojtěch Kundrát, Kristýna Bukvišová, Libor Novák, Lukáš Průcha, Lothar Houben, Jakub Zálešák, Antonio Vukusic, David Holec, Reshef Tenne, Jiří Pinkas
Abstract
High Resolution Image Download MS PowerPoint Slide Tungsten suboxide W 18 O 49 nanowhiskers are a material of great interest due to their potential high-end applications in electronics, near-infrared light shielding, catalysis, and gas sensing. The present study introduces three main approaches for the fundamental understanding of W 18 O 49 nanowhisker growth and structure. First, W 18 O 49 nanowhiskers were grown from γ-WO 3 / a -SiO 2 nanofibers in situ in a scanning electron microscope (SEM) utilizing a specially designed microreactor (μReactor). It was found that irradiation by the electron beam slows the growth kinetics of the W 18 O 49 nanowhisker, markedly. Following this, an in situ TEM study led to some new fundamental understanding of the growth mode of the crystal shear planes in the W 18 O 49 nanowhisker and the formation of a domain (bundle) structure. High-resolution scanning transmission electron microscopy analysis of a cross-sectioned W 18 O 49 nanowhisker revealed the well-documented pentagonal Magnéli columns and hexagonal channel characteristics for this phase. Furthermore, a highly crystalline and oriented domain structure and previously unreported mixed structural arrangement of tungsten oxide polyhedrons were analyzed. The tungsten oxide phases found in the cross section of the W 18 O 49 nanowhisker were analyzed by nanodiffraction and electron energy loss spectroscopy (EELS), which were discussed and compared in light of theoretical calculations based on the density functional theory method. Finally, the knowledge gained from the in situ SEM and TEM experiments was valorized in developing a multigram synthesis of W 18 O 49 / a -SiO 2 urchin-like nanofibers in a flow reactor.