Direct assessment of the acidity of individual surface hydroxyls

The state of deprotonation/protonation of surfaces has far-ranging implications in chemistry, from acid-base catalysis(1) and the electrocatalytic and photocatalytic splitting of water(2), to the behaviour of minerals(3) and biochemistry(4). An entity's acidity is described by its proton affinity and its acid dissociation constant pK(a) (the negative logarithm of the equilibrium constant of the proton transfer reaction in solution). The acidity of individual sites is difficult to assess for solids, compared with molecules. For mineral surfaces, the acidity is estimated by semi-empirical concepts, such as bond-order valence sums(5), and increasingly modelled with first-principles molecular dynamics simulations(6,7). At present, such predictions cannot be tested-experimental measures, such as the point of zero charge(8), integrate over the whole surface or, in some cases, individual crystal facets(9). Here we assess the acidity of individual hydroxyl groups on In2O3(111)-a model oxide with four different types of surface oxygen atom. We probe the strength of their hydrogen bonds with the tip of a non-contact atomic force microscope and find quantitative agreement with density functional theory calculations. By relating the results to known proton affinities of gas-phase molecules, we determine the proton affinity of the different surface sites of In2O3 with atomic precision. Measurements on hydroxylated titanium dioxide and zirconium oxide extend our method to other oxides. Non-contact atomic force microscopy measurements are used to probe the hydrogen bond strength of individual surface hydroxyl groups and determine their acidity with atomic precision.

Automated summary

The state of deprotonation/protonation of surfaces has significant implications in chemistry, affecting acid-base catalysis, water splitting, mineral behavior, and biochemistry. This study explores the acidity of individual hydroxyl groups on In2O3(111) surfaces, finding quantitative agreement between experimental measurements and theoretical calculations. The findings extend to other oxides like titanium dioxide and zirconium oxide, showcasing the ability to determine acidity with atomic precision using non-contact atomic force microscopy measurements.