Articles you may be interested inHydrogen stability in hydrogenated amorphous carbon films with polymer-like and diamond-like structure J. Appl. Phys. 112, 093502 (2012); 10.1063/1.4764001Pulsed laser deposition of hydrogenated amorphous diamondlike carbon films from a polymer target Formation of electrically conductive nitrogendoped amorphous hydrogenated carbon (diamondlike carbon) films by the supermagnetron plasma chemical vapor deposition method
The dependence of the preferred microhydration sites of 4-aminobenzonitrile (4ABN) on electronic excitation and ionization is determined through IR spectroscopy of its clusters with water (W) in a supersonic expansion and through quantum chemical calculations. IR spectra of neutral 4ABN and two isomers of its hydrogen-bonded (H-bonded) 4ABN-W complexes are obtained in the ground and first excited singlet states (S0, S1) through IR depletion spectroscopy associated with resonance-enhanced multiphoton ionization. Spectral analysis reveals that electronic excitation does not change the H-bonding motif of each isomer, that is, H2O binding either to the CN or the NH site of 4ABN, denoted as 4ABN-W(CN) and 4ABN-W(NH), respectively. The IR spectra of 4ABN(+)-W in the doublet cation ground electronic state (D0) are measured by generating them either in an electron ionization source (EI-IR) or through resonant multiphoton ionization (REMPI-IR). The EI-IR spectrum shows only transitions of the most stable isomer of the cation, which is assigned to 4ABN(+)-W(NH). The REMPI-IR spectrum obtained through isomer-selective resonant photoionization of 4ABN-W(NH) is essentially the same as the EI-IR spectrum. The REMPI-IR spectrum obtained by ionizing 4ABN-W(CN) is also similar to that of the 4ABN(+)-W(NH) isomer, but differs from that calculated for 4ABN(+)-W(CN), indicating that the H2O ligand migrates from the CN to the NH site upon ionization with a yield of 100%. The mechanism of this CN→NH site-switching reaction is discussed in the light of the calculated potential energy surface and the role of intracluster vibrational energy redistribution.
The dynamics and energetics of water at interfaces or in biological systems plays a fundamental role in all solvation and biological phenomena in aqueous solution. In particular, the migration of water molecules is the first step that controls the overall process in the time domain. Experimentally, the dynamics of individual water molecules is nearly impossible to follow in solution, because signals from molecules in heterogeneous environments overlap. Although molecular dynamics simulations do not have this restriction, there is a lack of experimental data to validate the calculated dynamics. Here, we demonstrate a new strategy, in which the calculated dynamics are verified by measured time-resolved infrared spectra. The coexistence of fast and slow migrations of water molecules around a CONH peptide linkage is revealed for a model system representative of a hydrate peptide.
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.