Issue 18, 2024

Size limits and fission channels of doubly charged noble gas clusters

Abstract

Small, highly charged liquid droplets are unstable with respect to spontaneous charge separation when their size drops below the Rayleigh limit or, in other words, their fissility parameter X exceeds the value 1. The absence of small doubly charged atomic cluster ions in mass spectra below an element-specific appearance size na has sometimes been attributed to the onset of barrierless fission at X = 1. However, more realistic models suggest that na marks the size below which the rate of fission surpasses that of competing dissociative channels, and the Rayleigh limit of doubly charged van der Waals clusters has remained unchartered. Here we explore a novel approach to form small dicationic clusters, namely by Penning ionization of singly charged noble gas (Ng) clusters that are embedded in helium nanodroplets; the dications are then gently extracted from the nanodroplets by low-energy collisions with helium gas. We observe Ngn2+ ions that are about 40% smaller than previously reported for xenon and krypton and about 20% for argon. These findings suggest that fission barriers have been underestimated in previous theoretical work. Furthermore, we measure the size distributions of fragment ions that are produced by collisional excitation of mass-selected dications. At lowest collision gas pressure, dicationic Kr and Xe clusters that are smaller than previously observed are found to evaporate an atom before they undergo highly symmetric fission. The distribution of fragments resulting from fission of small dicationic Ar clusters is bimodal.

Graphical abstract: Size limits and fission channels of doubly charged noble gas clusters

Supplementary files

Article information

Article type
Paper
Submitted
15 Feb 2024
Accepted
25 Mar 2024
First published
26 Mar 2024
This article is Open Access
Creative Commons BY license

Phys. Chem. Chem. Phys., 2024,26, 13923-13936

Size limits and fission channels of doubly charged noble gas clusters

I. Stromberg, S. Bergmeister, L. Ganner, F. Zappa, P. Scheier, O. Echt and E. Gruber, Phys. Chem. Chem. Phys., 2024, 26, 13923 DOI: 10.1039/D4CP00658E

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