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Atomic monolayer deposition on the surface of nanotube mechanical resonators

We studied monolayers of noble gas atoms (Xe, Kr, Ar, and Ne) deposited on individual ultra- clean suspended nanotubes. For this, we recorded the resonance frequency of the mechanical motion of the nanotube, since it provides a direct measure of the coverage. The latter is the number of adsorbed atoms divided by the number of the carbon atoms of the suspended nanotube. Monolayers formed when the temperature was lowered in a constant pressure of noble gas atoms. The coverage of Xe monolayers remained constant at 1/6 over a large temperature range. This finding reveals that Xe monolayers are solid phases with a triangular atomic arrangement, and are commensurate with the underlying carbon nanotube. By comparing our measurements to theoretical calculations, we identify the phases of Ar and Ne monolayers as fluids, and we tentatively describe Kr monolayers as solid phases. These results underscore that mechanical resonators made from single nanotubes are excellent probes for surface science.

preprint2014arXivOpen access
Alexandros TavernarakisJulien ChasteAlexander EichlerGustavo CeballosMaria Carmen GordilloJordi BoronatAdrian Bachtold
cond-mat.mes-hall
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Alexandros TavernarakisJulien ChasteAlexander EichlerGustavo CeballosMaria Carmen GordilloJordi BoronatAdrian Bachtold

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