TY - JOUR
T1 - A density functional theory computational study of adsorption of Di-Meta-Cyano Azobenzene molecules on Si (111) surfaces
AU - Soumehsaraei, Benyamin
AU - Taherifar, Neda
AU - Wu, Bisheng
AU - Tang, Wenxin
AU - Liu, Jefferson Zhe
PY - 2017/11/15
Y1 - 2017/11/15
N2 - The adsorption of di-meta-cyano azobenzene (DMC) cis and trans isomers on non-passivated and passivated Si (111) (7 × 7) surfaces is studied using density functional theory (DFT) calculations. Our results reveal that on the non-passivated surface the 12 Si adatoms are accessible to form chemical bonds with DMC molecules. Interestingly, the trans isomer forms two chemical bonds near the corner hole atom in Si (111) (7 × 7) surface, which is not observed in the widely studied metallic surfaces. The DMC isomers show significant structural distortion in the chemisorption case. The strong chemical bonds (and high bonding energy) could be detrimental to conformation switching between these two isomers under external stimuli. The physisorption case is also examined. Monte Carlo (MC) simulations with empirical force fields were employed to search about 106 different adsorption positions and DMC molecule orientations to identify the stable adsorption sites (up to six). The DFT-PBE and DFT-D2 calculations were then carried out to obtain the relaxed atomistic structures and accurate adsorption energy. We find that it is imperative to take van der Waals (vdW) interaction into account in DFT calculations. Our results show that the adsorption sites generally are encompassed by either the Si adatoms or the passivated H atoms, which could enhance the long-range dispersion interaction between DMC molecules and Si surfaces. The molecular structures of both isomers remain unchanged compared with gas phase. The obtained adsorption energy results ΔEads are moderate (0.2–0.8 eV). At some adsorption sites on the passivated surface, both isomers have similar moderate ΔEads (0.4–0.6 eV), implying promises of molecular switching that should be examined in experiments.
AB - The adsorption of di-meta-cyano azobenzene (DMC) cis and trans isomers on non-passivated and passivated Si (111) (7 × 7) surfaces is studied using density functional theory (DFT) calculations. Our results reveal that on the non-passivated surface the 12 Si adatoms are accessible to form chemical bonds with DMC molecules. Interestingly, the trans isomer forms two chemical bonds near the corner hole atom in Si (111) (7 × 7) surface, which is not observed in the widely studied metallic surfaces. The DMC isomers show significant structural distortion in the chemisorption case. The strong chemical bonds (and high bonding energy) could be detrimental to conformation switching between these two isomers under external stimuli. The physisorption case is also examined. Monte Carlo (MC) simulations with empirical force fields were employed to search about 106 different adsorption positions and DMC molecule orientations to identify the stable adsorption sites (up to six). The DFT-PBE and DFT-D2 calculations were then carried out to obtain the relaxed atomistic structures and accurate adsorption energy. We find that it is imperative to take van der Waals (vdW) interaction into account in DFT calculations. Our results show that the adsorption sites generally are encompassed by either the Si adatoms or the passivated H atoms, which could enhance the long-range dispersion interaction between DMC molecules and Si surfaces. The molecular structures of both isomers remain unchanged compared with gas phase. The obtained adsorption energy results ΔEads are moderate (0.2–0.8 eV). At some adsorption sites on the passivated surface, both isomers have similar moderate ΔEads (0.4–0.6 eV), implying promises of molecular switching that should be examined in experiments.
KW - Di-meta-cyano azobenzene molecule
KW - Molecular switch
KW - Si (111) surfaces
KW - Smart surfaces
UR - http://www.scopus.com/inward/record.url?scp=85020484688&partnerID=8YFLogxK
U2 - 10.1016/j.apsusc.2017.05.240
DO - 10.1016/j.apsusc.2017.05.240
M3 - Article
AN - SCOPUS:85020484688
SN - 0169-4332
VL - 422
SP - 557
EP - 565
JO - Applied Surface Science
JF - Applied Surface Science
ER -