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Mechanism of WS 2 Nanotube Formation Revealed by in Situ / ex Situ Imaging.

Vojtěch KundrátLibor NovákKristýna BukvišováJakub ZálešákEva KolíbalováRita RosentsveigC N R RaoHila ShalomLena YadgarovAlla ZakMiroslav KolíbalReshef Tenne
Published in: ACS nano (2024)
Multiwall WS 2 nanotubes have been synthesized from W 18 O 49 nanowhiskers in substantial amounts for more than a decade. The established growth model is based on the "surface-inward" mechanism, whereby the high-temperature reaction with H 2 S starts on the nanowhisker surface, and the oxide-to-sulfide conversion progresses inward until hollow-core multiwall WS 2 nanotubes are obtained. In the present work, an upgraded in situ SEM μReactor with H 2 and H 2 S sources has been conceived to study the growth mechanism in detail. A hitherto undescribed growth mechanism, named "receding oxide core", which complements the "surface-inward" model, is observed and kinetically evaluated. Initially, the nanowhisker is passivated by several WS 2 layers via the surface-inward reaction. At this point, the diffusion of H 2 S through the already existing outer layers becomes exceedingly sluggish, and the surface-inward reaction is slowed down appreciably. Subsequently, the tungsten suboxide core is anisotropically volatilized within the core close to its tips. The oxide vapors within the core lead to its partial out-diffusion, partially forming a cavity that expands with reaction time. Additionally, the oxide vapors react with the internalized H 2 S gas, forming fresh WS 2 layers in the cavity of the nascent nanotube. The rate of the receding oxide core mode increases with temperatures above 900 °C. The growth of nanotubes in the atmospheric pressure flow reactor is carried out as well, showing that the proposed growth model (receding oxide core) is also relevant under regular reaction parameters. The current study comprehensively explains the WS 2 nanotube growth mechanism, combining the known model with contemporary insight.
Keyphrases
  • carbon nanotubes
  • wastewater treatment
  • mass spectrometry
  • air pollution
  • particulate matter
  • molecularly imprinted
  • fluorescence imaging
  • solid phase extraction