Self-Limiting Adsorption of WO3 Oligomers on Oxide Substrates in Solution

Müllner, M. and Balajka, J. and Schmid, M. and Diebold, U. and Mertens, S.F.L. (2017) Self-Limiting Adsorption of WO3 Oligomers on Oxide Substrates in Solution. Journal of Physical Chemistry C, 121 (36). pp. 19743-19750. ISSN 1932-7447

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Abstract

Electrochemical surface science of oxides is an emerging field with expected high impact in developing, for instance, rationally designed catalysts. The aim in such catalysts is to replace noble metals by earth-abundant elements, yet without sacrificing activity. Gaining an atomic-level understanding of such systems hinges on the use of experimental surface characterization techniques such as scanning tunneling microscopy (STM), in which tungsten tips have been the most widely used probes, both in vacuum and under electrochemical conditions. Here, we present an in situ STM study with atomic resolution that shows how tungsten(VI) oxide, spontaneously generated at a W STM tip, forms 1D adsorbates on oxide substrates. By comparing the behavior of rutile TiO2(110) and magnetite Fe3O4(001) in aqueous solution, we hypothesize that, below the point of zero charge of the oxide substrate, electrostatics causes water-soluble WO3 to efficiently adsorb and form linear chains in a self-limiting manner up to submonolayer coverage. The 1D oligomers can be manipulated and nanopatterned in situ with a scanning probe tip. As WO3 spontaneously forms under all conditions of potential and pH at the tungsten-aqueous solution interface, this phenomenon also identifies an important caveat regarding the usability of tungsten tips in electrochemical surface science of oxides and other highly adsorptive materials. (Chemical Equation Presented).

Item Type:
Journal Article
Journal or Publication Title:
Journal of Physical Chemistry C
Uncontrolled Keywords:
/dk/atira/pure/subjectarea/asjc/2500/2508
Subjects:
?? catalystsinterfaces (materials)oligomersoxide mineralsphase interfacesscanning tunneling microscopysolutionssubstratesadsorptive materialschemical equationselectrochemical conditionselectrochemical surface sciencepoint of zero chargesolution interfacesubm ??
ID Code:
132976
Deposited By:
Deposited On:
18 Apr 2019 08:30
Refereed?:
Yes
Published?:
Published
Last Modified:
16 Jul 2024 11:06