0000000000297577
AUTHOR
S.v. Kuznetsov
Time resolved photofragmentation of Au $_{n}^{+}$ and Ag $_{n}^{+}$ clusters (n = 9, 21)
Gold and silver cluster ions were produced by laser vaporization and stored in a Penning trap. After mass selection the cluster sizes of interest were illuminated by a laser pulse and electronically excited. Photoabsorption cross sections and fragmentation patterns were measured for photon energies of 2.3 eV to 5.2 eV. Unimolecular dissociation was observed time resolved on a microsecond to millisecond scale. Dissociation energies were deduced from the measured life times.
Chemisorption of hydrogen on charged vanadium clusters
Abstract The chemisorption of hydrogen on positively charged vanadium clusters, V n + ( n = 1–17), was studied by measuring reaction rates and saturation coverages. Vanadium clusters are produced by laser vaporization and are injected into a Penning trap. Rates of the reaction V n + +H 2 → V n + H 2 are measured by axial ejection of all ions out of the trap after variable storage times and subsequent time-of-flight detection. An odd-even effect of the reaction rate is observed with odd clusters being more reactive. Clusters with low reactivity are found to be highly stable, as reflected by the respective separation energies of atoms. The number of adsorbed hydrogen atoms, m , is determined …
Au n+-induced decomposition of N2O
Reactions between small gold cluster ions, Au, and N2O were studied in a Penning trap mass spectrometer. Gold clusters were produced by laser vaporization and injected into a Penning trap. After reaction times of 50–7000ms the products were detected by time-of-flight mass spectrometry. For the major reaction channel, Au + N2OAu1,2N + NO+, rates of (0.9±0.1)×10−12 cm3 s−1 and (2.4±0.4)×10−12 cm3 s−1 were determined which are about a factor 500 below the collision rate. The corresponding activation energies for N2O decomposition were estimated to lie below 0.6 eV and 0.3 eV. Additional products with small branching ratios were detected, viz. the ions Au1O+, Au1N2O+, Au2N+, Au2NO+, Au2N2O+, Au…