• Title of article

    Selective adsorption of cations on single-walled carbon nanotubes: A density functional theory study

  • Author/Authors

    Wang، نويسنده , , Dan and Lu، نويسنده , , Jing and Zhou، نويسنده , , Jing-Erh Lai، نويسنده , , Lin and Wang، نويسنده , , LU and LUO، نويسنده , , Guangfu and Gao، نويسنده , , Zhengxiang and Li، نويسنده , , Guangping and Mei، نويسنده , , Wai Ning and Nagase، نويسنده , , Shigeru and Maeda، نويسنده , , Yutaka and Akasaka، نويسنده , , Takeshi and Zhou، نويسنده , , Yunsong، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2008
  • Pages
    6
  • From page
    886
  • To page
    891
  • Abstract
    The selective adsorption of NO 2 + cation on single-walled carbon nanotubes (SWNTs) is systemically studied by using density functional theory calculations. It is found that the adsorption energy of cations on SWNTs depends on the concentration of cations and the diameter and the electronic structure of SWNTs. The binding strength of NO 2 + on each SWNT increases monotonically as the concentration of NO 2 + decreases, undergoing a change from endothermic to exothermic reaction. Generally speaking, the binding of NO 2 + on SWNTs becomes weaker as the diameter increases. In the medium-diameter region (9 < d < 11 إ), NO 2 + prefers to interact with metallic SWNTs (m-SWNTs) rather than semiconducting SWNTs (s-SWNTs) at the same concentration of NO 2 + . In the small-diameter region (d < 9 إ), the binding of NO 2 + is nearly independent of metallicity, but it is stronger than that of on the medium-diameter s-SWNTs. In the large-diameter region (d > 11 إ), the dependence of adsorption on the electronic structure is complicated, but the binding of NO 2 + is weaker than that on the medium-diameter s-SWNTs. Our results are in agreement with the experimental report that the small-diameter m- and s-SWNTs and the medium-diameter m-SWNTs are etched away by NO 2 + while the medium-diameter s-SWNTs and the large-diameter m- and s-SWNTs are intact.
  • Keywords
    Single-walled carbon nanotube , Density functional calculation
  • Journal title
    Computational Materials Science
  • Serial Year
    2008
  • Journal title
    Computational Materials Science
  • Record number

    1683707