6533b7d1fe1ef96bd125c15d

RESEARCH PRODUCT

Dissociation mechanisms of cluster ions resolved using ab-initio molecular orbital calculations

Y. MizunoM. KageyamaS.t. NakagawaM. ItohI. SuzueH.j. Whitlow

subject

Nuclear and High Energy PhysicsChemistryBinding energyAb initioDissociation (chemistry)IonCrystallographyNuclear Energy and EngineeringAb initio quantum chemistry methodsIonizationCluster (physics)General Materials ScienceMolecular orbitalAtomic physics

description

We have examined the cluster-size effect on fragments in the collision-induced dissociation (CID) of small boron clusters (B + n , n ≤ 8) by means of ab-initio molecular orbital (MO) calculation, for conditions representative of low-Z cationic clusters in plasma. Single cations B + (leaving B 0 n-1 ) are predominantly fragmented from small clusters B + n (n < 5) by low-energy collisions (<10 eV) with Xe atoms. With increasing the size n, beyond n = 5, B + n-1 (leaving B°) clusters are observed preferentially. This alternating trend in experiment has not been quantitatively explained by previous ab-initio MO calculations. We used a density functional method called B3LYP and basis functions 6-31+G** including diffuse functions, and have succeeded in reproducing the alternation of the competing two dissociation processes as cluster size increases. In addition, the accuracy of ionization potentials and binding energies were also improved.

yearjournalcountryeditionlanguage
2007-06-01Journal of Nuclear Materials
https://doi.org/10.1016/j.jnucmat.2007.01.181