Stabilization of molecular hydrogen-bonded chains by carbon nanotubes

Abstract

We study numerically nonlinear dynamics of several types of molecular systems composed of hydrogen-bonded chains placed inside carbon nanotubes with open edges. We demonstrate that carbon nanotubes provide a stabilization mechanism for quasi-one-dimensional molecular chains via the formation of their secondary structures. In particular, a polypeptide chain (Gly)N placed inside a carbon nanotube can form of a stable helical chain (310, α, π and β-helix) with parallel chains of hydrogen-bonded peptide groups. A chain of hydrogen fluoride molecules can form hydrogen-bonded zigzag chain. We reveal that in such geometries the hydrogen-bonded chains may remain stable even at T=500~K. Thus, our results suggest that the use of carbon nanotubes with encapsulated hydrogen fluoride molecules may support high proton conductivity operating at high temperatures.