C. Goletti scite author profile

The pivotal importance of TiO2 as a technological material involves most applications in an aqueous environment, but the single‐crystal TiO2/bulk‐water interfaces are almost completely unexplored, since up to date solid/liquid interfaces are more difficult to access than surfaces in ultrahigh vacuum (UHV). Only a few techniques (as scanning probe microscopy) offer the opportunity to explore these systems under realistic conditions. The rutile TiO2(110) surface immersed in high‐purity water is studied by in situ scanning tunneling microscopy. The large‐scale surface morphology as obtained after preparation under UHV conditions remains unchanged upon prolonged exposure to bulk water. Moreover, in contrast to UHV, atomically resolved images show a twofold periodicity along the [001] direction, indicative of an ordered structure resulting from the hydration layer. This is consistent with density‐functional theory based molecular dynamics simulations where neighboring interfacial molecules of the first water layer in contact with the bulk liquid form dimers. By contrast, this dimerization is not observed for a single adsorbed water monolayer, i.e., in the absence of bulk water.

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Coexistence of Negatively and Positively Buckled Isomers onn+-DopedSi(111)−2×1

Bussetti

Bonanni

Cirilli

et al. 2011

Phys. Rev. Lett.

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A long-standing puzzle regarding the Si(111) − 2 × 1 surface has been solved. The surface energy gap previously determined by photoemission on heavily n-doped crystals was not compatible with a strongly bound exciton known from other considerations to exist. New low-temperature angle-resolved photoemission and scanning tunneling microscopy data, together with theory, unambiguously reveal that isomers with opposite bucklings and different energy gaps coexist on such surfaces. The subtle energetics between the isomers, dependent on doping, leads to a reconciliation of all previous results.

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Surface−Enhanced Polymerization via Schiff-Base Coupling at the Solid–Water Interface under pH Control

et al. 2015

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On-surface polymerization realized at the solid-liquid interface represents a promising route to obtain stable and conductive organic layers with tunable properties. We present here spectroscopic evidence of π-conjugated polymer formation at the interface between an iodinemodified Au(111) and an aqueous solution. Schiff-base coupling has been used to drive the reaction by changing the pH. Scanning tunneling microscopy (STM) investigations show that the substrate acts as a template driving the formation of 1D ordered nanostructures. All the chemical states of the molecules on the surface have been identified and their evolution as a function of the pH has been monitored by synchrotron radiation X-ray photoelectron spectroscopy (XPS), demonstrating that two polymeric phases, undistinguishable by STM, exist on the surface: intermediate state and π-conjugated final product. The I/Au(111) substrate enhances the formation of π-conjugated polymers, as established comparing their production on the surface and in the bulk solution.

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C. Goletti

Molecular Ordering at the Interface Between Liquid Water and Rutile TiO₂(110)

Coexistence of Negatively and Positively Buckled Isomers onn+-DopedSi(111)−2×1

Surface−Enhanced Polymerization via Schiff-Base Coupling at the Solid–Water Interface under pH Control

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C. Goletti

Molecular Ordering at the Interface Between Liquid Water and Rutile TiO2(110)

Coexistence of Negatively and Positively Buckled Isomers onn+-DopedSi(111)−2×1

Surface−Enhanced Polymerization via Schiff-Base Coupling at the Solid–Water Interface under pH Control

Contact Info

Product

Resources

About

Molecular Ordering at the Interface Between Liquid Water and Rutile TiO₂(110)