Theoretical study of NO₂ adsorption on SiCNT and P-doped SiCNT

The release of NO₂ into atmosphere, mainly coming from the combustion of fuel, has brought serious pollution on the environment. In order to detect and remove it, the adsorptions of NO₂ on pristine silicon carbon nanotube (SiCNT) and phosphorus-doped silicon carbon nanotube (P-SiCNT) were investigated theoretically based on density functional theory (DFT) and grand-canonical Monte Carlo (GCMC) method, including the geometrical structures, adsorption energies, electronic structures, sensitivities, recovery time and the selectivity for the adsorption of NO₂ in high humidity environment. To dope the SiCNT, a carbon or silicon atom was replaced with a phosphorus atom to build P_C-SiCNT and P_Si-SiCNT. It is found that when NO₂ is adsorbed on the surface or inside SiCNT, P_C-SiCNT and P_Si-SiCNT, respectively, the largest adsorption energies are −34.53 kcal/mol for M1-NO₂-SiCNT, −64.41 kcal/mol for M1-NO₂-P_C-SiCNT, −57.04 kcal/mol for M1-NO₂-P_Si-SiCNT, respectively, which are all belong to chemical adsorption. For the adsorption NO₂ on SiCNT to form M1-NO₂-SiCNT and NO₂-SiCNT, the adsorption systems keep p-type semiconductor properties with a slight decrease of band gap. While for the adsorption NO₂ on P_C-SiCNT and P_Si-SiCNT to form M1-NO₂-P_C-SiCNT, NO₂-P_C-SiCNT, M1-NO₂-P_Si-SiCNT and NO₂-P_Si-SiCNT, the adsorption systems are converted to p-type semiconductor from metal. Furthermore, the sensitivities were also calculated based on the band gap, and it is found that P_C-SiCNT and P_Si-SiCNT have superior sensing performance in detecting NO₂. Therefore, P-SiCNTs may have potential application not only adsorbent but also gas sensors of NO₂. For the adsorption configurations with the largest adsorption energies, the suitable desorption temperatures within 1 min are 553 K for M1-NO₂-SiCNT, 1023 K for M1-NO₂-P_C-SiCNT and 913 K for M1-NO₂-P_Si-SiCNT, respectively, which makes the recycle of SiCNT, P_C-SiCNT and P_Si-SiCNT possible. Meanwhile, the effect of the humidity was also explored, and it is found that the humidity has slight effect on the adsorption of NO₂ for above nanotubes.