Nanodiamonds exhibit exceptional
colloidal properties in aqueous
media that lead to a wide range of applications in nanomedicine and
other fields. Nevertheless, the role of surface chemistry on the hydration
of nanodiamonds remains poorly understood. Here, we probed the water
hydrogen bond network in aqueous dispersions of nanodiamonds by infrared,
Raman, and X-ray absorption spectroscopies applied in situ in aqueous
environment. Aqueous dispersions of nanodiamonds with hydrogenated,
carboxylated, hydroxylated, and polyfunctional surface terminations
were compared. A different hydrogen bond network was found in hydrogenated
nanodiamonds dispersions compared to dispersions of nanodiamonds with
other surface terminations. Although no hydrogen bonds are formed
between water and hydrogenated surface groups, a long-range disruption
of the water hydrogen bond network is evidenced in hydrogenated nanodiamonds
dispersion. We propose that this unusual hydration structure results
from electron accumulation at the diamond–water interface.
In situ O K-edge X-ray absorption
fine structure (XAFS) spectroscopy
was applied to investigate the electronic and structural change in
the nickel–borate (Ni–Bi) electrocatalyst
during the oxygen evolution reaction (OER). An absorption peak was
observed around 528.7 eV at 1.0 V versus Ag/AgCl in a potassium borate
aqueous solution, which relates with the formation of nanoscale order
domains of edge-sharing NiO6 octahedra in the Ni–Bi electrocatalyst. XAFS spectra were measured with variation
of the electrode potential from 0.3 up to 1.0 V. The measured absorption
peaks suggest that the quantity of NiO6 octahedra increased
in correlation with the OER current; however, when the potential was
changed downward, the XAFS absorption peak assigned to NiO6 octahedra remained constant, even at the electrode potential for
no OER current. This difference implies that the water oxidation catalysis
proceeds at the domain edge of NiO6 octahedra. The XAFS
technique provides the first successful direct probing of the active
species in the Ni–Bi electrocatalyst during electrochemical
reaction.
Liquid methanol shows one- and two-dimensional (1D/2D) hydrogen bond (HB) networks, and liquid water shows three-dimensional (3D) HB networks. We have clearly found three different local structures around the methyl group of methanol-water binary solutions (CH3OH)X(H2O)1-X at different concentrations in C K-edge soft X-ray absorption spectroscopy (XAS). With the help of molecular dynamics simulations, we have discussed the concentration dependence of the hydrophobic interaction at the methyl group in the C K-edge XAS spectra. In the methanol-rich region I (1.0 > X > 0.7), a small amount of water molecules exists separately around dominant 1D/2D HB networks of methanol clusters. In the region II (0.7 > X > 0.3), the hydrophobic interaction of the methyl group is dominant due to the increase of mixed methanol-water 3D network structures. In the water-rich region III (0.3 > X > 0.05), methanol molecules are separately embedded in dominant 3D HB networks of water. On the other hand, the pre-edge feature in the O K-edge XAS shows almost linear concentration dependence. It means the HB interaction between methanol and water is almost the same as that of water-water and of methanol-methanol.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.