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Abstract
The speciation of beryllium chloride solutions has been investigated using electrospray ionization mass spectrometry in both positive and negative ion modes. The majority of observed species were mixed beryllium-chlorido-oxido-hydroxido species, with the degree of hydration of the observed ions depending on the number of chloride ions. The observed species contain between 1 and 6 Be ions. The interactions of BeCl2 with a selection of crown ether ligands and cryptand[2.2.2] were also investigated using ESI MS. These ligands have low affinity for Be2+, instead the observed ions are dominated by species formed from adventitious Na+ or K+ ions. The crown ether 12-crown-4 showed the most complex spectra, as a result of greater interactions with Be2+, as evidenced by observed ions such as [BeX(12-crown-4)]+ (X = Cl or OH). The interactions of crown ethers with beryllium ions (as well as coordinated Cl- or OH- ancillary ligands) were investigated using Density Functional Theory [B3LYP/6-311++G(dp)], where it was shown that the species [BeX(crown ether)]+ (X = Cl or OH) are considerably more stable than [Be(crown ether)]2+ species, with 12-crown-4 forming the most stable complex. The combination of ESI MS and DFT investigations indicates that full encapsulation of the Be2+ by crown ethers is unfavorable, and coordination with an accompanying hydroxide or chloride is preferred.
Graphical Abstract
Acknowledgements
We thank the Marsden Fund of the New Zealand Government (contract MAU1204), administered by the Royal Society of New Zealand, for financial support of this work. OR thanks Wendy Jackson and Pat Gread for technical support. We also thank the reviewers for helpful comments.
Disclosure statement
No potential conflict of interest was reported by the author(s).