Abstract
To probe the ability of ions to enter and leave a nanotube interior, we calculated the energetic of a direct diffusion pathway for H+, Li+, Na+, K+ cations to move through the (3,3), (4,4) and (5,5) open-ended single-walled carbon nanotubes (SWNTs) with ab initio techniques. For three nanotubes, there is no energy barrier for the Li+ ions to enter the open tubes. In fact, there is a net decrease in the energy of the system, showing that the nanotubes actually act as an attractor for the Li+ ions. Similar results also hold for the H+ and Na+ ions into (4,4) nanotube. These ions can easily diffuse and leave the nanotube from other side. H+ strongly attract with the (3,3) nanotube but cannot diffuse and is trapped. Our results show that the entry of K+ and Na+ ions into (3,3) nanotube is forbidden. In contrast, (4,4) and (5,5) nanotubes for H+ and K+ ions and (5,5) nanotubes for Na+ act as ion channels that conduct these ions. In all NT-H systems and (3,3) NT-Li system, the charge transferred between ion and nanotube and nanotube achieve the positive charge.