Abstract
The ability to synthesize nanoparticles (NPs), here TiO2, of different shapes in a controlled and reproducible way is of high significance for a wide range of fields including catalysis and materials design. Different NP shapes exhibit variations of emerging facets, and processes such as adsorption, diffusion, and catalytic activity are, in general, facet sensitive. Therefore, NP properties, e.g., the reactivity of NPs or the stability of assembled NPs, depend on their shape. We combine computational modeling based on density functional theory with experimental techniques such as transmission electron microscopy, energy-dispersive x-ray spectroscopy, and x-ray powder diffraction to investigate the ability of various adsorbates, including hydrohalic and carboxylic acids, to influence NP shape. This approach allows us to identify mechanisms stabilizing specific surface facets and thus to predict NP shapes using computational model systems and to experimentally characterize the synthesized NPs in detail. Shape-controlled anatase TiO2 NPs are synthesized here in agreement with the calculations in platelet and bi-pyramidal shapes by employing different precursors. The importance of the physical conditions and chemical environment during synthesis, e.g., via competitive adsorption or changes in the chemical potentials, is studied via ab initio thermodynamics, which allows us to set previous and new results in a broader context and to highlight potentials for additional synthesis routes and NP shapes.
Highlights
Titania (TiO2) nanoparticles (NPs) are commercially available and used in applications ranging from pigments in sunscreen and other cosmetic products to catalysis.1 Because of its bandgap, abundance, stability, and low toxicity, TiO2 is especially attractive for photocatalysis, photovoltaics, and batteries.2,3 A recent study even showed that TiO2 NPs can be used as support for Pt atoms in the emerging field of single atom catalysis.4 TiO2 NPs can be assembled in a three-dimensional structure to form hybrid materials with extraordinary mechanical strength5,6 and adjustable elasticity.7 Most of these applications depend on the interaction ofTiO2 surfaces with the surrounding medium and certain types of functional chemical groups
We combine computational modeling based on density functional theory with experimental techniques such as transmission electron microscopy, energy-dispersive x-ray spectroscopy, and x-ray powder diffraction to investigate the ability of various adsorbates, including hydrohalic and carboxylic acids, to influence NP shape
In accordance with the results presented here, a combined experimental and theoretical study found that the reconstruction is not the thermodynamic ground state in benzoic acid and HF aqueous solutions and only formed at temperatures above 550 ○C.33
Summary
Titania (TiO2) nanoparticles (NPs) are commercially available and used in applications ranging from pigments in sunscreen and other cosmetic products to catalysis. Because of its bandgap, abundance, stability, and low toxicity, TiO2 is especially attractive for photocatalysis, photovoltaics, and batteries. A recent study even showed that TiO2 NPs can be used as support for Pt atoms in the emerging field of single atom catalysis. TiO2 NPs can be assembled in a three-dimensional structure to form hybrid materials with extraordinary mechanical strength and adjustable elasticity. Most of these applications depend on the interaction ofTiO2 surfaces with the surrounding medium and certain types of functional chemical groups. Titania (TiO2) nanoparticles (NPs) are commercially available and used in applications ranging from pigments in sunscreen and other cosmetic products to catalysis.. A recent study even showed that TiO2 NPs can be used as support for Pt atoms in the emerging field of single atom catalysis.. TiO2 NPs can be assembled in a three-dimensional structure to form hybrid materials with extraordinary mechanical strength and adjustable elasticity.. TiO2 NPs can be assembled in a three-dimensional structure to form hybrid materials with extraordinary mechanical strength and adjustable elasticity.7 Most of these applications depend on the interaction of. TiO2 surfaces with the surrounding medium and certain types of functional chemical groups. Shape-control during the synthesis of TiO2 NPs is of crucial importance
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