Minimum sizes for the submersion of alkali clusters into liquid helium

Alkali atoms do not stably embed in liquid helium-4 because the interatomic attractive potential is unable to overcome the short-range Pauli repulsion of the s electrons and the surface tension cost of the surrounding bubble. Similarly, small alkali complexes reside on the surface of helium nanodroplets instead of inside. However, as the size of the metal cluster increases, its van der Waals attraction to the helium matrix grows faster than the repulsive energies and above a certain size it should become favorable for clusters to submerge in the liquid. Based on an evaluation of the relevant energy terms, we characterize the bubble dimensions and estimate the critical submersion sizes. The latter range from N20 for Li_N and Na_N to N>100 for Rb_N in helium-4 and from N5 for Li_N and Na_N to N~20 for Cs_N in helium-3. These results are discussed in the context of nanodroplet pick-up experiments with alkali atoms