Desorption of cluster ions from solid Ne by low-energy ion impact

Abstract: Abstract. We investigated Ne+ ions and Ne + n (n = 2 − 20) cluster ions desorbed from the surface of solid Ne by 1.0 keV Ar + ion impact. Kinetic energy analysis shows a considerably narrower energy distribution for the Ne + n (n ≥ 3) ions than for the Ne + n (n = 1, 2) ions. The dependence of ion yields on Ne film thickness indicates that cluster ions (n ≥ 3) are desorbed only from relatively thick films. We conclude that desorbed ions grow into large cluster ions during the outflow of deep bulk atoms to the … Show more

“…This charge-up phenomenon is mostly caused by emission of secondary electrons generated by the ion impacts. In fact, the desorption energy is known to be below 2 eV, as measured for 120 MLs solid Ne, for which no charge-up effect is expected [14]. The kinetic energy of Ar + 2 photodesorbed from solid Ar was reported to be less than 1 eV [15].…”

“…The kinetic energies of Ne + n (n = 1 − 3) decrease with size, while those of Ne + n (n ≥ 4) ions are largely independent of size. A detailed discussion of the process of Ne-cluster-ion formation and the dependence of kinetic energy on cluster size is given elsewhere [14].…”

Temperature effects on ion-desorption dynamics from solid Ne by low-energy ion impacts

“…This charge-up phenomenon is mostly caused by emission of secondary electrons generated by the ion impacts. In fact, the desorption energy is known to be below 2 eV, as measured for 120 MLs solid Ne, for which no charge-up effect is expected [14]. The kinetic energy of Ar + 2 photodesorbed from solid Ar was reported to be less than 1 eV [15].…”

“…The kinetic energies of Ne + n (n = 1 − 3) decrease with size, while those of Ne + n (n ≥ 4) ions are largely independent of size. A detailed discussion of the process of Ne-cluster-ion formation and the dependence of kinetic energy on cluster size is given elsewhere [14].…”

Temperature effects on ion-desorption dynamics from solid Ne by low-energy ion impacts

“…We will discuss the results within the framework of the CE mechanism, and we also performed a simple trajectory calculation of desorbed excited Ne atoms. Figure 1 shows a side view of the experimental setup, which was similar to the one we used in our previous work [3][4][5], except for the addition of a low-energy electron gun and a channel electron multiplier (CEM) for the detection of desorbed metastable atoms. The main chamber was evacuated by a series of turbo molecular pumps and a Ti-getter pump, resulting in a pressure of approximately 3·10 -8 Pa.…”

Temperature effect of metastable atom desorption from solid Ne by low-energy electron impact

System for coincidence measurements of the ions desorbed and projectiles scattered from noble gas solid surfaces by slow multiply charged ion impacts